Constitution and fabrication of flat-panel display and porous-faced structure suitable for partial of full use in spacer of flat-panel display

Information

  • Patent Grant
  • 6734608
  • Patent Number
    6,734,608
  • Date Filed
    Thursday, January 25, 2001
    23 years ago
  • Date Issued
    Tuesday, May 11, 2004
    20 years ago
Abstract
A structure suitable for partial or full use in a spacer (24) of a flat-panel display has a porous face (54). The structure may be formed with multiple aggregates (100) of coated particles (102) bonded together in an open manner to form pores (58). A coating (88) consisting primarily of carbon and having a highly uniform thickness may extend into pores of a porous body (46). The coating can be created by removing non-carbon material from carbon-containing species provided along the pores. A solid porous film (82) whose thickness is normally no more than 20 μm has a resistivity of 108-1014 ohm-cm. A spacer for a flat-panel display contains a support body (80) and an overlying, normally porous, layer (82) whose resistivity is greater parallel to a face of the support body than perpendicular to the body's face.
Description




FIELD OF USE




This invention relates to flat-panel displays of the cathode-ray tube (“CRT”) type, including the manufacture of flat-panel CRT displays. This invention also relates to the constitution and fabrication of structures that can be partially or fully utilized in flat-panel CRT displays.




BACKGROUND




A flat-panel CRT display basically consists of an electron-emitting component and a light-emitting component. The electron-emitting component, commonly referred to as a cathode, contains electron-emissive regions that emit electrons over a relatively wide area. The emitted electrons are suitably directed towards light-emissive elements distributed over a corresponding area in the light-emitting component. Upon being struck by the electrons, the light-emissive elements emit light that produces an image on the display's viewing surface.




The electron-emitting and light-emitting components are connected together to form a sealed enclosure normally maintained at a pressure much less than 1 atm. The exterior-to-interior pressure differential across the display is typically in the vicinity of 1 atm. In a flat-panel CRT display of significant viewing area, e.g., at least 10 cm


2


, the electron-emitting and light-emitting components are normally incapable of resisting the exterior-to-interior pressure differential on their own. Accordingly, a spacer (or support) system is conventionally provided inside the sealed enclosure to prevent air pressure and other external forces from collapsing the display.




The spacer system typically consists of a group of laterally separated spacers positioned so as to not be directly visible on the viewing surface. The presence of the spacer system can adversely affect the flow of electrons through the display. For example, electrons coming from various sources occasionally strike the spacer system, causing it to become electrically charged. The electric potential field in the vicinity of the spacer system changes. The trajectories of electrons emitted by the electron-emitting device are thereby affected, often leading to degradation in the image produced on the viewing surface.




More particularly, electrons that strike a body, such as a spacer system in a flat-panel display, are conventionally referred to as primary electrons. When the body is struck by primary electrons of high energy, e.g., greater than 90 eV, the body normally emits secondary electrons of relatively low energy. More than one secondary electron is, on the average, typically emitted by the body in response to each high-energy primary electron striking the body. Although electrons are often supplied to the body from one or more other sources, the fact that the number of outgoing (secondary) electrons exceeds the number of incoming (primary) electrons commonly results in a net positive charge building up on the body.




It is desirable to reduce the amount of positive charge buildup on a spacer system in a flat-panel CRT display. Jin et al, U.S. Pat. No. 5,598,056, describes one technique for doing so. In Jin et al, each spacer in the display's spacer system is a pillar consisting of multiple layers that extend laterally relative to the electron-emitting and light-emitting components. The layers in each spacer pillar alternate between an electrically insulating layer and an electrically conductive layer. The insulating layers are recessed with respect to the conductive layers so as to form grooves. When secondary electrons are emitted by the spacers in Jin et al, the grooves trap some of the secondary electrons and prevent them from escaping the spacers. Because fewer secondary electrons escape the spacers than what would occur if the grooves were absent, the amount of positive charge buildup on the spacers is reduced.




The technique employed in Jin et al to reduce positive charge buildup is creative. However, the spacers in Jin et al are relatively complex and pose significant concerns in dimensional tolerance and, therefore, in reliability. Manufacturing the spacers in Jin et al could be problemsome. It is desirable to have a relatively simple technique, including a simple spacer design, for reducing charge buildup on a spacer system of a flat-panel CRT display.




GENERAL DISCLOSURE OF THE INVENTION




The present invention furnishes a variety of structures that are porous, at least along a face of each structure. Each of the porous structures, or a portion of each structure, is typically suitable for use in a spacer of a flat-panel CRT display. The present invention also furnishes techniques for manufacturing such porous-faced structures, including methods for manufacturing flat-panel displays.




A porous-faced spacer constituted according to the invention lies between a pair of plate structures of a flat-panel display. An image is supplied by one of the plate structures in response to electrons provided from the other plate structure. Somewhat similar to what occurs in Jin et al, the porosity along the face of the spacer creates facial roughness that prevents some secondary electrons emitted by the spacer from escaping the spacer. Accordingly, positive charge buildup on the spacer is reduced. The image is thereby improved.




In one structure configured according to the invention, multiple particle aggregates are bonded together in an open manner to form a solid porous body in which pores extend between the particle aggregates. The pores inhibit secondary electrons emitted by the porous body from escaping the body. Each particle aggregate contains multiple coated particles bonded together. Each of the coated particles is formed with a support particle and a particle coating that overlies at least part of the support particle.




The particle coatings preferably consist of material which, when struck by high-energy primary electrons, emit fewer secondary electrons than the material that forms the support particles. Candidate materials for the particle coatings are oxides and hydroxides of titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten, including oxide and/or hydroxide of two or more of these metals. The particle coating material may also contain carbon.




Candidate materials for the support particles include a substantial number of oxides and hydroxides of metals, especially transition metals, and metal-like elements. In particular, the oxides and hydroxides of the non-carbon elements in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, including the lanthanides, are candidates for the support particles. This includes oxide and/or hydroxide of two or more of these non-carbon elements. As an example, when oxide and/or hydroxide of one or more of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium is utilized in the support particles, oxide and/or hydroxide of one or more of titanium, chromium, manganese, iron, zirconium, cerium, and neodymium is typically utilized in the particle coatings. The particle coatings are typically of different chemical composition than the support particles.




Various process sequences can be utilized in accordance with the invention to form a solid porous structure that contains multiple aggregates of coated particles. For instance, starting with (separate) aggregates of support particles, the support-particle aggregates can be bonded together in an open manner to form bonded aggregates of the support particles. Particle coatings are then provided over the support particles in the so-bonded aggregates to form the desired porous structure. Alternatively, the particle coatings can be provided over the support particles before or during the bonding of the support-particle aggregates. As another alternative, the particle coatings can be provided over (separate) support particles before or during particle bonding to form aggregates of the coated particles. The coated particle aggregates are then bonded together to form the desired solid porous structure.




When a porous-faced spacer of the present flat-panel display utilizes part or all of a porous structure containing multiple aggregates of particles bonded together in an open manner to form pores, the particles may include uncoated particles. That is, each of the particles need not have a particle coating that overlies a generally distinct, typically earlier formed, support particle.




In another structure configured according to the invention, a porous body has a face along which multiple primary pores extend into the body. A coating overlies a face of the porous body and extends along the primary pores so as to coat their surfaces without substantially closing them. The resulting pores in the combination of the porous body and the coating are referred to here as further pores. The coating normally consists principally of carbon. The carbon-containing coating typically has a thickness of 1-100 nm when the average diameter of the primary pores is 5-1,000 nm. Since the further pores are carbon-coated versions of the primary pores, the average diameter of the further pores is less than that of the primary pores and can be as little as 1 nm.




The thickness of the carbon-containing coating is normally highly uniform, especially along the pores. Specifically, the standard deviation in the thickness of the coating is preferably no more than 20%, more preferably no more than 10%, of the average thickness of the coating.




When the structure that contains the present carbon-containing coating is employed in a spacer of a flat-panel CRT display, the carbon in the coating normally emits fewer secondary electrons than what would occur from the underlying material of the porous body if the coating were absent. Making the coating thickness highly uniform enables the coating to be made quite thin without significantly exposing the underlying porous body and thereby increasing the secondary electron emission. The spacer normally dissipates less power as the coating is made thinner. Hence, achieving the present coating thickness uniformity leads, advantageously, to a reduction in power dissipation while avoiding an increase in secondary electron emission and an attendant increase in positive charge buildup on the spacer.




One technique for making a carbon-coated porous body according to the invention begins with precursor material that has multiple carbon-containing, normally organic, groups. A porous body is formed from the precursor material according to a process in which molecules of the precursor material cross-link while retaining at least part of the carbon-containing groups. When the precursor material is part of a liquidous composition, the ends of the carbon-containing groups typically move into the liquid so that the retained carbon-containing groups coat the surfaces of pores in the body.




The porous body is subsequently treated to remove non-carbon constituents of the retained carbon-containing groups, at least along exposed surface of the porous body. This may entail pyrolizing the retained carbon-containing groups or/and subjecting them to phenomena such as a plasma, an electron beam, ultraviolet light, or a reducing environment. In any event, the treating step furnishes the porous body with a rough face constituted principally with carbon.




Another technique for making a carbon-coated porous body in accordance with the invention begins with a porous body having a porosity of at least 10% along a rough face of the body. The porous body is subjected to carbon-containing chain molecules, each having at least one leaving species and at least one carbon-containing chain. The carbon-containing chain molecules chemically bond to the porous body, largely by reactions that involve only the leaving species. At least one leaving species is normally released from each carbon-containing chain molecule as it bonds to the porous body. Non-carbon constituents are subsequently removed from the so-bonded chain molecules. The porous body is thereby furnished with a carbon-containing coating.




In a further structure configured according to the invention, a solid porous film consists principally of oxide and/or hydroxide. Candidates for the oxide and/or hydroxide are oxides and/or hydroxides of non-carbon elements in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, again including the lanthanides. Preferably, the oxide and/or hydroxide includes oxide and/or hydroxide of one or more of silicon, titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten, including oxide and/or hydroxide of two or more of these elements. The porous film has a porosity of at least 10% along a face of the film and an average thickness of no more than 20 μm. The average electrical resistivity of the film is 10


8


-10


14


ohm-cm, preferably 10


9


-10


13


ohm-cm, at 25° C.




A porous film that contains oxide and/or hydroxide is typically created by initially forming a liquid-containing film that includes precursor material of the oxide and/or hydroxide. The precursor material may be polymeric in nature and/or may consist of particles. The liquid-containing film is then processed to remove liquid from the film and convert it into a solid porous film having the porosity, thickness, and electrical resistivity properties specified above.




The film processing is normally conducted in such a way that atoms of the precursor material bond to one another in forming the solid porous film. Gas evolution from the precursor material and/or the liquid may be employed to create or enhance the solid film's porosity. Also, the precursor material may include sacrificial carbon-containing, normally organic, material. After creating a solid film from the liquid-containing film, porosity is produced or enhanced in the solid film by removing non-carbon material, and typically also carbon, of the sacrificial part of the precursor material. A generally conformal coating may be provided over the solid porous film.




Each of the foregoing structures is, as mentioned above, utilized partially or wholly in a porous-faced spacer of a flat-panel display configured according to the invention. The porous-faced spacer lies between a first plate structure and an oppositely situated second plate structure. The first plate structure emits electrons. The second plate structure emits light upon receiving electrons emitted by the first plate structure.




Some high-energy primary electrons usually strike the spacer during display operation, causing the spacer to emit secondary electrons. The so-emitted secondary electrons are, on the average, normally of significantly lower energy than the primary electrons. Due to the porosity-produced roughness in the spacer's face, the lower-energy secondary electrons are more prone to impact the spacer and be captured by it than what would occur if the spacer's face were smooth. The lower-energy secondary electrons captured by the spacer cause relatively little further secondary electron emission from the spacer. The porosity along the spacer's face thereby causes the overall amount of secondary electron emission to be reduced.




Primary electrons which strike the spacer include electrons that follow trajectories directly from the first plate structure to the spacer as well as electrons that reflect off the second plate structure after having traveled from the first plate structure to the second plate structure. The reflected electrons are generally referred to as “backscattered” electrons. While the flat-panel display can normally be controlled so that only a small fraction of the electrons emitted by the first plate structure directly strike the spacer, the backscattered electrons travel in a broad distribution of directions as they leave the second plate structure. As a result, electron backscattering off the second plate structure is difficult to control direction-wise. By inhibiting secondary electrons emitted by the present spacer from escaping the spacer, the spacer facial porosity also reduces spacer charging that would otherwise result from backscattered primary electrons striking the spacer.




In another aspect of the invention, a spacer situated between a pair of plate structures of a flat-panel display that operates in the preceding manner is provided with a directional resistivity characteristic for enhancing display performance. For this purpose, a substantially unitary primary layer overlies a face of a support body of the spacer. The spacer's primary layer, although unitary in nature, is normally porous. The primary layer has a higher electrical resistivity parallel to the face of the support body than perpendicular to the support body's face. More particularly, the average resistivity of the layer parallel to the body's face is typically at least twice, preferably at least ten times, the average resistivity of the layer perpendicular to the body's face.




By providing the spacer with the foregoing directional resistivity characteristic, the relatively low resistivity perpendicular to the face of the spacer's support body enables charge that accumulates on the spacer due to primary electrons striking the spacer to be rapidly transferred from the outside of the spacer through the coating to the support body and then removed from the spacer. On the other hand, the relatively high resistivity parallel to the support body's face serves to limit the current that flows through the primary layer from either plate structure to the other plate structure. Power dissipation is reduced. The display can operate efficiently without incurring significant charge buildup on the spacer. Also, the functions of controlling charge buildup and handling current flow from one plate structure to the other are substantially decoupled, thereby facilitating spacer design.




The primary layer of the spacer typically includes a base layer and a plurality of resistivity-modifying regions. The base layer overlies the face of the support body. The resistivity-modifying regions occupy laterally separated sites laterally surrounded by the base layer. The resistivity-modifying regions, preferably formed with carbon, are of lower average resistivity than the base layer. As a result, the resistivity of the primary layer is higher parallel to the support body's face than perpendicular to the body's face.




In accordance with the invention, a primary layer with a directional resistivity characteristic is typically created by initially forming a liquid-containing body that includes carbon particles and precursor material. The liquid-containing body is then processed to remove liquid from the body and convert it into a porous body through which most of the carbon particles largely penetrate. Atoms of the precursor material, which may be polymeric and/or consist of particles, normally bond to one another in forming the porous body. The porous body then constitutes a base layer of the primary layer, while the carbon particles constitute resistivity-modifying regions.




To the extent that the spacer used in the present flat-panel display has multiple levels of spacer material, the levels typically extend vertically relative to the electron-emitting and light-emitting components rather than laterally as in Jin et al. A spacer with vertically extending spacer-material levels is generally simpler in design, and can be fabricated to high tolerances more easily, than a spacer having laterally extending spacer-material levels. When the present spacer has multiple vertically extending levels of spacer material, reliability concerns associated with the spacer design are considerably less severe than those that arise with the spacer design of Jin et al. When the spacer used in the present display has only a single level of spacer material, the display essentially avoids the reliability concerns that arise in Jin et al. The net result is a large advance over the prior art.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a general cross-sectional side view of a flat-panel CRT display having a spacer system configured according to the invention.





FIG. 2

is an exploded cross-sectional view of a portion of the flat-panel display of

FIG. 1

centered around one of the wall-shaped spacers in the spacer system.





FIG. 3

is a cross-sectional view of a section of the display portion in FIG.


2


.





FIG. 4

is a general graph of electron yield as a function of electron departure energy, largely secondary-electron departure energy, for a spacer wall in the spacer system of the flat-panel display in FIG.


1


.





FIGS. 5



a


-


5




d


are cross-sectional side views of four general embodiments of structures suitable for the main wall of the wall-shaped spacer in FIG.


2


.





FIGS. 6



a


-


6




d


are cross-sectional side views representing a set of steps that employ the invention's teachings for creating a porous-faced structure suitable for full or partial use in the main spacer wall of

FIG. 5



a


or


5




c.







FIG. 7

is a cross-sectional view of a section of the display portion in

FIG. 2

in which one porous layer in the main spacer wall of

FIG. 5



c


is implemented with aggregates of particles according to the invention.





FIGS. 8



a


and


8




b


are cross-sectional views of two ways of implementing the particle aggregates in FIG.


7


.





FIGS. 9



a


and


9




b


are cross-sectional side views representing a pair of steps in forming aggregates of support particles according to the invention.





FIGS. 10



a


-


10




d


are cross-sectional side views representing a set of steps that employ the invention's teachings for creating a porous layer from the particle aggregates in

FIG. 9



b


so that the particle aggregates appear generally as shown in

FIG. 8



a.







FIGS. 11



a


-


11




d


are cross-sectional side views representing another set of steps that employ the invention's teachings for creating a porous layer from the particle aggregates in

FIG. 9



b


so that the particle aggregates appear generally as shown in

FIG. 8



a.







FIGS. 12



a


-


12




d


are cross-sectional side views representing a set of steps that utilize the invention's teachings for creating a porous layer of particle aggregates that appear generally as shown in

FIG. 8



b.







FIG. 13

is a cross-sectional view of a section of the display portion in

FIG. 2

in which one porous layer in the main spacer wall of

FIG. 5



c


is implemented with a carbon-coated porous body according to the invention.





FIGS. 14



a


-


14




c


are cross-sectional side views representing a set of steps that employ the invention's teachings for creating a carbon-coated porous layer suitable for partial or full use in the main spacer wall of FIG.


13


.





FIGS. 15



a


-


15




c


are cross-sectional side views representing a set of steps that employ the invention's teachings for creating a carbon-coated porous layer suitable for full or partial use in the main spacer wall of

FIG. 5



c.







FIG. 16

is an exploded cross-sectional view of part of the porous layer in

FIG. 15



c.







FIG. 17

is a cross-sectional view of a section of the display portion in

FIG. 2

in which the main spacer wall of

FIG. 5



a


or


5




c


utilizes a layer having a directional electrical resistivity characteristic in accordance with the invention.





FIG. 18

is a cross-sectional view of an implementation of the display portion in FIG.


17


.





FIGS. 19



a


-


19




c


are cross-sectional side views representing a set of steps that employ the invention's teachings for creating a porous layer which has a directional resistivity characteristic and which is suitable for partial or full use in the main spacer wall of FIG.


17


.











The symbol “e


1







” in the drawings represents a primary electron. The symbol “e


2







” in the drawings represents a secondary electron.




Like reference symbols are employed in the drawings and in the description of the preferred embodiments to represent the same, or very similar, item or items.




DESCRIPTION OF THE PREFERRED EMBODIMENTS




General Display Configuration




An internal spacer system for a flat-panel CRT display configured and fabricated according to the invention is formed with spacers that are porous along their faces for reducing spacer charging during display operation. Primary electron emission in the present flat-panel CRT display typically occurs according to field-emission principles. A field-emission flat-panel CRT display (often referred to as a field-emission display) having a spacer system configured according to the invention can serve as a flat-panel television or a flat-panel video monitor for a personal computer, a lap-top computer, or a workstation.




In the following description, the term “electrically insulating” (or “dielectric”) generally applies to materials having an electrical resistivity greater than 10


12


ohm-cm at 25° C. The term “electrically non-insulating” thus refers to materials having an electrical resistivity of up to 10


12


ohm-cm at 25° C. Electrically non-insulating materials are divided into (a) electrically conductive materials for which the electrical resistivity is less than 1 ohm-cm at 25° C. and (b) electrically resistive materials for which the electrical resistivity is in the range of 1 ohm-cm to 10


12


ohm-cm at 25° C. Similarly, the term “electrically non-conductive” refers to materials having an electrical resistivity of at least 1 ohm-cm at 25° C., and includes electrically resistive and electrically insulating materials. These categories are determined at an electric field of no more than 10 volts/μm.





FIG. 1

illustrates a field-emission display (“FED”) configured in accordance with the invention. The FED of

FIG. 1

contains an electron-emitting backplate structure


20


, a light-emitting faceplate structure


22


, and a spacer system situated between plate structures


20


and


22


. The spacer system resists external forces exerted on the display and maintains a largely constant spacing between structures


20


and


22


.




In the FED of

FIG. 1

, the spacer system consists of a group of laterally separated largely identical spacers


24


generally shaped as relatively flat walls. Each of spacer walls


24


is porous at least along its opposing faces.

FIG. 1

is presented at too large a scale to conveniently depict the facial roughness that results from the porous nature of spacer walls


24


. The spacer wall facial roughness is pictorially illustrated in certain of the later drawings, starting with FIG.


2


. Returning to

FIG. 1

, each spacer wall


24


extends generally perpendicular to the plane of the figure. Plate structures


20


and


22


are connected together through an annular peripheral outer wall (not shown) to form a high-vacuum sealed enclosure


26


in which spacer walls


24


are situated.




Backplate structure


20


contains an array of rows and columns of laterally separated electron-emissive regions


30


that face enclosure


26


. Electron-emissive regions


30


overlie an electrically insulating backplate (not separately shown) of plate structure


20


. Each electron-emissive region


30


normally consists of a large number of electron-emissive elements shaped in various ways such as cones, filaments, or randomly shaped particles. Plate structure


20


also includes a system (also not separately shown) for focusing electrons emitted by regions


30


.





FIG. 1

depicts a column of electron-emissive regions


30


. The row direction extends into the plane of FIG.


1


. Each spacer wall


24


contacts backplate structure


20


between a pair of rows of regions


30


. Each consecutive pair of walls


24


is separated by multiple rows of regions


30


.




Faceplate structure


22


contains an array of rows and columns of laterally separated light-emissive elements


32


formed with light-emissive material such as phosphor. Light-emissive elements


32


overlie a transparent electrically insulating faceplate (not separately shown) of plate structure


22


. Each electron-emissive element


32


is situated directly opposite a corresponding one of electron-emissive regions


30


. The light emitted by elements


32


forms an image on the display's viewing surface at the exterior surface of faceplate structure


22


.




The FED of

FIG. 1

may be a black-and-white or color display. Each light-emissive element


32


and corresponding electron-emissive region


30


form a pixel in the black-and-white case, and a sub-pixel in the color case. A color pixel typically consists of three sub-pixels, one for red, another for green, and a third for blue.




A border region


34


of dark, typically black material laterally surrounds each of light-emissive elements


32


above the faceplate. Border region


34


, referred to here as a black matrix, is typically raised relative to light-emissive elements


32


. In view of this and to assist in pictorially distinguishing elements


32


from black matrix


34


,

FIG. 1

illustrates black matrix


34


as extending further towards backplate structure


20


than do elements


32


. Compared to elements


32


, black matrix


34


is substantially non-emissive of light when struck by electrons emitted from regions


30


in backplate structure


20


.




In addition to components


32


and


34


, faceplate structure


22


contains an anode (not separately shown) situated over or under components


32


and


34


. During display operation, the anode is furnished with a potential that attracts electrons to light-emissive elements


32


.




During FED operation, electron-emissive regions


30


are controlled to emit primary electrons that selectively move toward faceplate structure


22


. The electrons so emitted by each region


30


preferably strike corresponding target light-emissive element


32


, causing it to emit light. Item


38


in

FIG. 1

represents the trajectory of a typical primary electron traveling from one of regions


30


to corresponding element


32


. The forward electron-travel direction is thus from backplate structure


20


to faceplate structure


22


generally parallel to spacer walls


24


and thus generally perpendicular to plate structure


20


or


22


.




Some of the primary electrons emitted by each region


30


invariably strike parts of the display other than corresponding target light-emissive element


32


. To the extent that the emitted primary electrons are off-target, the control provided by the electron-focusing system and any other electron trajectory-control components of the FED display is normally of such a nature that the large majority of the off-target primary electrons strike black matrix


34


. However, off-target primary electrons occasionally follow trajectories directly from an electron-emissive element to nearest spacer wall


24


as represented by electron trajectory


40


in FIG.


1


. Such off-target primary electrons that strike spacer walls


24


are often of sufficiently high energy to cause walls


24


to emit secondary electrons.




Also, some of the primary electrons that travel from an electron-emissive region


30


to faceplate structure


22


are scattered backward off plate structure


22


rather than causing light emission. The reverse electron-travel direction is from faceplate structure


22


to backplate structure


20


generally parallel to spacer walls


24


. While the FED is normally controlled so that the vast majority of primary electrons emitted by each region


30


impact directly on or close to its target light-emissive element


32


, electrons scattered backward off faceplate structure


22


move initially in a broad distribution of directions. A substantial fraction of the backscattered electrons strike spacer walls


24


. Item


42


in

FIG. 1

represents the trajectory of a backscattered primary electron as it travels from a light-emissive element


32


to nearest spacer wall


24


. Backscattered primary electrons that strike spacer walls


24


are normally of sufficiently high energy to cause walls


24


to emit secondary electrons. Some of the backscattered electrons return to faceplate structure


22


and cause light emission or are further backscattered.





FIG. 2

presents an exploded view of one spacer wall


24


, including adjoining portions of plate structures


20


and


22


. The cross section of

FIG. 2

is rotated 90° counter-clockwise to that of FIG.


1


. With reference to

FIG. 2

, each spacer wall


24


consists of a rough-faced generally wall-shaped electrically non-conductive main spacer body


46


and one or more adjoining electrically non-insulating spacer wall electrodes represented here as electrodes


48


,


50


, and


52


. Although

FIG. 2

illustrates main spacer wall


46


as fully underlying spacer electrodes


48


,


50


, and


52


, one or more thin portions of main wall


46


may partially or fully overlie one or more of electrodes


48


,


50


, and


52


.




Main wall


46


has a pair of opposing rough faces


54


and


56


. The roughness in main wall faces


54


and


56


arises from pores


58


and


60


that extend into wall


46


respectively along wall faces


54


and


56


. Some of the primary electrons that strike a spacer wall


24


occasionally hit electrodes


48


,


50


, and


52


, primarily electrode


48


. However, as represented in

FIG. 2

where electron trajectories


40


and


42


terminate on rough face


54


, the large majority of these primary electrons strike face


54


or


56


.




Spacer wall electrodes


48


,


50


, and


52


preferably consist of electrically conductive material, typically metal such as aluminum, chromium, nickel, or gold, including a metallic alloy such as a nickel-vanadium alloy, or a combination of two or more of these metals. In any event, electrodes


48


,


50


, and


52


are of considerably lower average electrical resistivity than main wall


46


. Electrode


48


is a face electrode situated on wall face


54


. Another such face electrode (not shown) may be situated on wall face


56


opposite face electrode


48


. Electrodes


50


and


52


are end (or edge) electrodes situated on opposite ends (or edges) of main wall


46


so as to respectively contact plate structures


20


and


22


.




Wall electrodes


48


,


50


, and


52


cooperate with the electron-focusing system in controlling the movement of electrons from backplate structure


20


through sealed enclosure


26


to faceplate structure


22


. Further examples of how spacer wall electrodes, such as electrodes


48


,


50


, and


52


, function to control the forward electron movement are presented in Spindt et al, U.S. patent application Ser. No. 09/008,129, filed Jan. 16, 1998, now U.S. Pat. No. 6,049,165, and Spindt et al U.S. patent application Ser. No. 09/053,247, filed Mar. 31, 1998, now U.S. Pat. No. 6,107,731. The contents of Ser. Nos. 09/008,129 and 09/053,247 are incorporated by reference herein. Alternative implementations for electrodes


48


,


50


, and


52


are also presented in Ser. Nos. 09/008,129 and 09/053,247.




Pore Characteristics




Pores


58


and


60


in main spacer wall


46


are normally of irregular shape. Many of pores


58


intersect one another below an imaginary plane running along the top of rough wall face


54


. Some of pores


58


do not reach face


54


, i.e., they lie fully below the imaginary plane running along the top of face


54


. The same applies to pores


60


with respect to an imaginary plane running along the top (bottom in the orientation of

FIG. 2

) of rough wall face


56


.




Pores


58


and


60


are normally distributed in a generally random manner in main wall


46


. As discussed further below, pores


58


and


60


are normally present in a pair of thin layers along rough faces


54


and


56


. However, in some embodiments, pores


58


and


60


can be distributed largely throughout wall


46


. Pores


58


are typically present along largely all of face


54


. Likewise, pores


60


are typically present along largely all of face


56


. Pores


58


and


60


are normally similar to irregular pores in a sponge.




The term “porosity” is employed here in characterizing rough faces


54


and


56


of main wall


46


. The volume porosity of a porous body is the percentage of the body's volume occupied by the pores or/and other such openings in the porous body. The porosity of main wall


46


along face


54


or


56


, variously referred to here as the main wall facial porosity or the main wall porosity along face


54


or


56


, is therefore the percentage of area occupied by pores


58


or


60


along an imaginary plane running generally through face


54


or


56


along or near the tops of pores


58


or


60


.




Main wall


46


normally has a porosity of at least 10% along each of wall faces


54


and


56


. The main wall porosity along face


54


or


56


is preferably at least 20%, more preferably at least 40%. The main wall facial porosity is typically 60% or more, often up to 80% or more. In some embodiments, the main wall porosity along face


54


or


56


can reach 90% or more.




Pores


58


and


60


normally have an average pore diameter in the range of 1-1,000 nm. The average pore diameter is typically 5-1,000 nm, preferably 10-500 nm, more preferably 25-250 nm.




Effect of Facial Porosity on Electron Escape




An understanding of how the porosity-produced roughness in wall faces


54


and


56


reduces the fraction, and normally the number, of secondary electrons that escape main wall


46


is facilitated with the assistance of

FIGS. 3 and 4

.

FIG. 3

depicts a portion of spacer wall


24


along rough face


54


and an adjoining portion of faceplate structure


22


.

FIG. 4

illustrates how the number of electrons that escape a surface upon being struck by high-energy primary electrons of median striking (incident) energy ε


1SMD


varies with the energy ε


D


of the escaping electrons just as they depart from the surface. The number of electrons that escape a unit area of a smooth surface, or a projected unit area of a rough surface, at any value of electron departure energy ε


D


is the electron yield N


e


. The vast majority of electrons that escape such a surface are secondary elections. Consequently, energy ε


D


is largely the departure energy of escaping secondary electrons.




Referring to

FIG. 3

, secondary electrons are emitted by main wall


46


upon being struck by high-energy primary electrons traveling directly from backplate structure


20


, as represented by electron trajectory


40


, and by high-energy primary electrons backscattered off faceplate structure


22


, as represented by electron trajectory


42


, after traveling from backplate structure


20


to faceplate structure


22


. In

FIG. 3

, primary electron trajectories


40


and


42


respectively terminate in a pair of pores


58


along wall face


54


.




Items


70


in

FIG. 3

indicate examples of trajectories followed by secondary electrons emitted from a point in one pore


58


when main wall


46


is struck by a primary electron that follows trajectory


40


to that point. Items


72


indicate examples of trajectories followed by secondary electrons emitted from a point in another pore


58


when wall


46


is struck by a primary electron following trajectory


42


to the second point. As indicated by multiple secondary electron trajectories


70


or


72


for each primary electron trajectory


40


or


42


, the number of secondary electrons caused by each primary electron typically averages more than one.




An electric field {overscore (E)} is directed generally from faceplate structure


22


to backplate structure


20


. Electric field {overscore (E)} is the principal force that acts on secondary electrons emitted by main wall


46


. To a first approximation, trajectories


70


and


72


followed by the secondary electrons are roughly parabolic, at least in the immediate vicinity of wall


46


. Since electrons are negatively charged, trajectories


70


and


72


bend towards faceplate structure


22


as electric field {overscore (E)} causes the secondary electrons to be accelerated towards faceplate structure


22


.




The initial directions of secondary electrons that follow trajectories such as trajectories


70


and


72


are largely random. Some of the secondary electrons rapidly strike other points in pores


58


from which they were emitted. Other secondary electrons strike points in pores


58


from which they were emitted after their trajectories


70


or/and


72


bend significantly towards faceplate structure


22


. Yet other secondary electrons escape spacer wall


24


and follow trajectories


70


and


72


towards faceplate structure


22


.




A large majority of the electrons that return to main wall


46


impact wall


46


close to where they were emitted from wall


46


and therefore are of relatively low energy at impact. Consequently, these secondary electrons are largely captured by wall


46


. Because their energy is relatively low at impact, they also do not cause significant further secondary electron emission from wall


46


.




Whether a secondary electron is captured by, or escapes from, main wall


46


depends on a number of factors, including (a) the secondary electron's emission departure direction, (b) departure energy ε


2D


and thus the departure speed of the secondary electron, (c) where the primary electron strikes wall face


54


and therefore where the secondary electron is emitted from face


54


, (d) the characteristics of pores


58


along face


54


, and (e) the average magnitude of electric field {overscore (E)} between plate structures


20


and


22


.




Pores


58


along face


54


tend to trap secondary electrons by providing them with surfaces to hit and thereby be captured. Since a secondary electron is emitted from largely the point at which a primary electron strikes face


54


, the average probability of ;capturing a secondary electron emitted from a recessed area along face


54


normally increases as the emission-causing primary electron penetrates deeper into a pore


58


. The so-emitted secondary electron has increased distance to travel and, on the average, greater likelihood of traveling in an initial direction which results in the electron striking a point in that pore


58


than a secondary electron emitted from a shallower point in that pore


58


. In contrast, secondary electrons emitted from high points on face


54


have few places to contact face


54


and have low probabilities of being captured by face


54


.




If a completely smooth face were substituted for rough face


54


, there would be no recessed areas for secondary electrons to strike. A very high fraction of the secondary electrons emitted by the body having the smooth face would escape the body. Hence, pores


58


and


60


cause the fraction of emitted secondary electrons that escape main wall


46


to be less than the fraction of emitted secondary electrons that escape the smooth reference surface.




On the other hand, roughness in a surface appears to cause the number of secondary electrons to increase, at least for certain types of surface roughness. The increase in the number of secondary electrons emitted from such a rough surface varies with the energies of the primary electrons as they strike the rough surface and typically increases with increasing primary electron striking energy ε


1SMD


greater than approximately 1,000 eV. Whether the roughness in the surface leads to an increase or decrease in the total number of secondary electrons that actually escape the rough surface thus depends on the magnitudes of the incident energies of the primary electrons. In the FED that contains spacer wall


24


, the primary electrons strike wall face


54


or


56


with energies which, although high compared to median secondary-electron departure energy ε


2DMD


, are sufficiently low that the roughness produced by pores


58


and


60


causes a reduction in the total number of secondary electrons that escape main wall


46


and, accordingly, that escape spacer wall


24


.




Electric field {overscore (E)} causes backscattered primary electrons moving away from faceplate structure


22


to slow down. More specifically, the backscattered electrons lose velocity in the reverse electron-travel direction. To a first approximation, the backscattered electrons maintain the components of their velocity parallel to plate structure


22


or


20


. As a result, the backscattered electrons are more likely to penetrate deeper into pores


58


along wall face


54


than electrons traveling directly from backplate structure


20


to main wall


46


. Due to the deeper penetration of the backscattered primary electrons into pores


58


, the resulting secondary electrons emitted by wall


46


are more prone to be captured by wall


46


than the secondary electrons caused by primary electrons traveling directly from backplate structure


20


to wall


46


. The porosity-produced roughness in wall faces


54


and


56


thereby especially reduces positive spacer charging due to electron backscattering off faceplate structure


22


.




Two curves


76


and


78


are shown in FIG.


4


. Curve


76


represents the yield N


e


of electrons which escape a unit area of a flat smooth reference surface formed with material of the same chemical composition as the material that forms rough wall face


54


while high-energy primary electrons of median striking energy ε


1SMD


impact the smooth reference surface. This yield, referred to here as the “natural” electron yield, is normally determined for primary electrons that impinge perpendicularly on the reference surface. Curve


78


represents the yield N


e


of electrons that escape rough face


54


along a projected unit area of face


54


, i.e., along a unit area of an imaginary plane running through the top of face


54


, while high-energy primary electrons of median striking energy ε


1SMD


impact face


54


. The electron yield represented by curve


78


is referred to here as the “roughness-modified” electron yield.




The secondary electrons emitted by rough face


54


or the reference surface upon being struck by primary electrons of median striking energy ε


1SMD


have a median energy ε


2DMD


as they are emitted from, and therefore start to depart from, face


54


or the reference surface. Energy ε


2DMD


is referred to here as the median secondary-electron departure energy.




Each of curves


76


and


78


has two peaked portions as a function of electron departure energy ε


D


: a low-energy left-hand peak and a high-energy right-hand peak. In some cases, the left-hand peaks of curves


76




35


and


78


occur at, or essentially at, the vertical axis where departure energy ε


D


is zero. The left-hand peak of each of curves


76


and


78


tails off relatively slowly with increasing electron departure energy ε


D


. The end of the tail of each of the left-hand peaks occurs approximately at a dividing electron energy ε


DD


between median secondary-electron departure energy ε


2DMD


and primary-electron striking energy ε


1SMD


The right-hand peaks of curves


76


and


78


are much closer to each other than the left-hand peaks are to each other.




The low-energy left-hand peak of curve


76


largely represents the yield of secondary electrons that are emitted by, and escape from, the smooth reference surface as a function of electron departure energy ε


D


. Integration of the left-hand peak of curve


76


from zero to dividing energy ε


DD


largely gives the total natural secondary electron yield, i.e., the total number of electrons that escape a unit area of the reference surface. The ratio of the total natural secondary-electron yield to the total number of primary electrons that strike a unit area of the reference surface is the natural secondary electron yield coefficient δ.




The low-energy left-hand peak of curve


78


largely represents the yield of secondary electrons that actually escape main wall


46


along rough face


54


. Since some of the secondary electrons emitted from face


54


are subsequently captured by face


54


due to the spacer facial porosity, the left-hand peak of curve


78


is largely the difference, per projected unit area of face


54


, between the number of secondary emitted by face


54


and the number of secondary electrons captured by face


54


as a function of electron departure energy ε


D


. The left-hand peak of curve


78


is lower than the left-hand peak of curve


76


because primary electrons strike both (a) face


54


in the present FED and (b) the smooth reference surface with median primary-electron striking energy ε


1SMD


which, while generally high, is sufficiently low that the total number of secondary electrons which escape face


54


is less than the total number of secondary electrons which escape the reference surface.




Integration of the left-hand peak of curve


78


from zero to dividing energy ε


DD


largely gives the total roughness-modified secondary electron yield. The ratio of the total roughness-modified secondary electron yield to the total number of primary electrons that pass through a projected unit area of face


54


is the roughness-modified secondary electron yield coefficient δ*. Since (a) face


54


captures some of the emitted secondary electrons and (b) primary-electron striking energy ε


1SMD


is sufficiently low in the present FED, roughness-modified secondary electron yield coefficient δ* of face


54


is less than natural secondary electron yield coefficient δ of the (type of) material that forms face


54


.




Some of the high-energy primary electrons that strike rough face


54


or the smooth reference surface are reflected, or scattered, rather than causing secondary electron emission. The high-energy right-hand peaks of curves


76


and


78


largely represent primary electrons that scatter off face


54


or the reference surface and escape face


54


or the reference surface. Some of the primary electrons scattered off face


54


strike face


54


elsewhere, largely due to the spacer facial roughness, and cause secondary electron emission there. The effect of primary electrons that scatter off face


54


but do not escape face


54


is included within the roughness-modified secondary electron yield. Because secondary electrons emitted from face


54


are of lower departure energy ε


D


than primary electrons scattered off face


54


, the fraction of secondary electrons captured by face


54


is normally considerably greater than the fraction of scattered primary electrons captured by face


54


.




Electrons are emitted from rough face


54


or the smooth reference surface due to phenomena other than high-energy primary electrons striking face


54


or the reference surface. In

FIG. 4

, the number of electrons that escape face


54


or the reference surface as a result of other such phenomena is represented largely by the relatively low-level curve portion between the left-hand and right-hand peaks of corresponding curve


78


or


76


.




Integration of curve


76


from dividing energy ε


DD


to the right-hand edge of the right-hand peak gives the total natural non-secondary electron yield, i.e., the total number of scattered primary electrons and other non-secondary electrons that escape a unit area of the reference surface. The ratio of the total natural non-secondary electron yield to the total number of primary electrons that strike a unit area of reference surface is the natural non-secondary electron yield coefficient η. Similarly, integration of curve


78


from dividing energy ε


DD


to the right-hand end of the right-hand peak gives the total roughness-modified non-secondary electron yield. The ratio of the total roughness-modified non-secondary electron yield to the total number of electrons that pass through a projected unit area of face


54


is the roughness-modified non-secondary electron yield coefficient η*.




Curves


76


and


78


are quite close to each other over the integration range above dividing energy ε


DD


, curve


78


typically being no greater than curve


76


over this range. Hence, roughness-modified non-secondary electron yield coefficient η* is close to natural non-secondary electron yield coefficient η and, in any event, is no more than coefficient η.




The sum of natural secondary electron yield coefficient δ and natural non-secondary electron yield coefficient η is the total natural electron yield coefficient σ for the reference surface. Likewise, the sum of roughness-modified secondary electron yield coefficient δ* and roughness-modified non-secondary electron yield coefficient δ* is the total roughness-modified electron yield coefficient σ* for rough face


54


. As mentioned above, coefficient δ* is less than coefficient δ at the magnitude of median primary-electron striking energy ε


1SMD


typically present in the FED of the invention. Since coefficient η* is no more than coefficient η, total roughness-modified electron yield coefficient σ* of face


54


is less than natural electron yield coefficient σ of the material that forms face


54


at the ε


1SMD


magnitude which typically occurs in the present FED.




Natural coefficients σ, δ, and η, although determined for a smooth surface at specific primary electron impingement conditions (i.e., normal to the smooth surface), are generally considered to be properties of the material that forms the smooth surface. In the present situation, coefficients σ, δ, and η are properties of the material that forms wall face


54


without regard to the roughness in face


54


.




Electrical Characteristics, Constituency, and Internal Confiquration of Main Spacer Body




Main wall-shaped spacer body


46


normally has a sheet resistance of 10


8


-10


16


ohms/sq. The sheet resistance of main wall


46


is preferably 10


10


-10


14


ohms/sq., typically 10


11


-10


12


ohms/sq. Wall


46


normally has a breakdown voltage of at least 1 volt/μm. The wall breakdown voltage is preferably greater than 4 volts/μm, typically greater than 6 volts/μm.




Main wall


46


may be internally configured in various ways.

FIGS. 5



a


-


5




d


illustrate four basic internal configurations for main wall


46


. Each functionally different layer or coating in each configuration of

FIGS. 5



a


-


5




d


may consist of two or more layers or coatings that provide the indicated function. Wall


46


may also include one or more layers or coatings that provide functions besides those described below. Such additional components may be located above, between, or below the layers, coatings, and other components described below.




In

FIG. 5



a


, main wall


46


is a primary wall-shaped electrically non-conductive spacer body consisting of a wall-shaped electrically non-conductive core substrate


80


and a pair of porous electrically non-conductive layers


82


and


84


situated on the opposite faces of wall-shaped core substrate


80


. Porous layers


82


and


84


, which are largely identical, may connect to each other around the ends or side edges of core substrate


80


. The outside faces of layers


82


and


84


respectively form wall faces


54


and


56


. Irregular pores


58


are randomly distributed largely throughout layer


82


, while irregular pores


60


are randomly distributed largely throughout layer


84


.




Core substrate


80


normally has approximately the general electrical characteristics prescribed above for main wall


46


. Accordingly, the sheet resistance of core substrate


80


is normally approximately 10


8


-10


16


ohms/sq., preferably approximately 10


10


-10


14


ohms/sq., typically approximately 10


11


-10


12


ohms/sq. The breakdown voltage of substrate


80


is normally at least approximately 1 volt/μm, preferably more than approximately 4 volt/μm, typically more than approximately 6 volt/μm. Substrate


80


is typically electrically resistive but may be electrically insulating.




Subject to meeting the preceding electrical characteristics, substrate


80


normally consists of ceramic, including glass-like ceramic. Primary candidates for the material of substrate


80


are oxides and hydroxides of one or more non-carbon cation elements in Groups 2a, 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, including the lanthanides.




The phrase “or more” as used in describing elements contained in candidate materials for a body means that two or more of the identified elements, e.g., the cation elements here in Groups 2a, 3b, 4b 4b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, may be present in the identified body, e.g., core substrate


80


here.




The candidate materials may be in mixed form, such as a solid solution, a multi-phase mixture, a multi-phase mixture of solid solutions, and so on, with respect to the cation elements. For example, in the case of a solid solution of binary mixed oxide and/or binary mixed hydroxide, the body contains L


u


M


v


O


w


and/or L


x


M


y


(OH)


z


where L and M are different ones of the identified cation elements, e.g., the elements in Groups 2a, 3b, 4b, 4b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, u, v, w, x, y, and z are numbers, O is oxygen, and H is hydrogen. For a multi-phase mixture of binary mixed oxide and/or binary mixed hydroxide, the body contains L


u


O


w1


.M


v


O


w2


and/or L


x


(OH)


z1


.M


y


(OH)


z2


, where w


1


, w


2


, z


1


, and z


2


are numbers. Similarly, for a multi-phase mixture of solid solutions of binary mixed oxide and/or binary mixed hydroxide, the body contains L


u1


M


v1


O


w1


.L


u2


M


v2


O


w2


and/or L


x1


M


y1


(OH)


z1


.L


x2


M


y2


(OH)


z2


, where u


1


, v


1


, u


2


, v


2


, x


1


, y


1


, x


2


, and y


2


are numbers.




Particularly attractive oxide and hydroxide candidates for core substrate


80


are those of beryllium, magnesium, aluminum, silicon, titanium, vanadium, chromium, manganese, iron, yttrium, niobium, molybdenum, lanthanum, cerium, praseodymium, neodymium, europium, and tungsten, including mixed oxide and/or hydroxide of two or more of these elements. In a typical implementation, substrate


80


consists largely of oxide one or more of aluminum, titanium, chromium, and iron.




Other candidates for the material of core substrate


80


include nitrides of one or more non-carbon elements in Groups 3b, 4b, 4b, 6b, 7b, 8, 1b, 2b, 3b, and 4a of Periods 2-6 of the Periodic Table, including the lanthanides. Further candidates for the core substrate material are carbides of one or more non-carbon elements in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, again including the lanthanides. Particularly attractive nitride and carbide substrate candidates are aluminum nitride and silicon carbide. Multiple ones of the various oxide, hydroxide, nitride, and carbide materials may be present in substrate


80


.




The composition of core substrate


80


is typically relatively uniform throughout its bulk, i.e., away from the interfaces with porous layers


82


and


84


. The composition of the bulk of substrate


80


can, however, vary somewhat from place to place. Although substrate


80


may be porous, any pores in substrate


80


are normally considerably different from pores


58


and


60


. Any roughness along the faces of substrate


80


is normally considerably less than the porosity-produced roughness in wall faces


54


and


56


. Substrate


80


normally has a thickness of 10-100 μm, typically 50 μm.




Each of porous layers


82


and


84


is of much greater sheet resistance than core substrate


80


. Specifically, the sheet resistance of porous layer


82


or


84


is normally at least ten times, preferably at least one hundred times, the sheet resistance of substrate


80


. This corresponds to each of layers


82


and


84


normally being at least ten times, preferably being at least one hundred times, greater resistance per unit length than substrate


80


, the length dimension for resistance being taken from end electrode


52


to end electrode


50


(or vice versa). Equivalently stated, for the situation in which layers


82


and


84


each extend fully along the length of substrate


80


, the resistance of each of layers


82


and


84


is normally at least ten times, preferably at least one hundred times, the resistance of substrate


80


. With layers


82


and


84


being much more electrically resistive than substrate


80


, layers


82


and


84


determine the electron-emission characteristics of main wall


46


while substrate


80


determines the other electrical characteristics of wall


46


. This separation of electronic functions facilitates spacer design.




Each of porous layers


82


and


84


normally has an average electrical resistivity of 10


8


-10


14


ohm-cm at 25° C. The average electrical resistivity of layer


82


or


84


is preferably 10


9


-10


13


ohm-cm, more preferably 10


9


-10


12


ohm-cm, at 25° C. As mentioned above, electrically resistive materials have an electrical resistivity of 1-10


12


ohm-cm at 25° C., while electrically insulating materials have an electrical resistivity of greater than 10


12


ohm-cm at 25° C. Consequently, layers


82


and


84


may be electrically resistive or electrically insulating.




Each of porous layers


82


and


84


is usually no more than 20 μm thick. The minimum thickness of layer


82


or


84


is normally 2 nm. The average thickness of each of layers


82


and


84


is normally 10-1,000 nm, typically 20-500 nm.




Subject to meeting the preceding electrical characteristics, porous layers


82


and


84


normally consist of ceramic, including glass-like ceramic. Candidate materials for layers


82


and


84


are oxides and hydroxides of one or more non-carbon elements in Groups 3b, 4b, 4b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, including the lanthanides. Particularly attractive oxide and hydroxide candidates for layers


82


and


84


are those of silicon, titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten, including mixed oxide and/or hydroxide of two or more of these elements. Except for silicon, germanium, and tin, all of the particularly attractive oxides and hydroxides are oxides and hydroxides of transition metals.





FIG. 5



b


depicts an embodiment in which main wall


46


consists simply of a porous wall-shaped electrically non-conductive primary substrate


86


. Pores


58


and


60


are randomly distributed largely throughout primary substrate


86


and basically form a single group of pores. The porosity of substrate


86


can vary from the center of substrate


86


to its faces


54


and


56


.




The composition of primary substrate


86


is typically relatively uniform throughout its bulk, i.e., away from rough faces


54


and


56


. The composition of the bulk of substrate


86


can, however, vary somewhat from place to place. The composition of the material that forms faces


54


and


56


may be largely the same as, or somewhat different from, the material that forms the bulk of substrate


86


.




Primary substrate


86


has substantially the general electrical characteristics prescribed above for main wall


46


. That is, the sheet resistance of substrate


86


is normally 10


8


-10


16


ohms/sq., preferably 10


10


-10


14


ohms/sq., typically 10


11


-10


12


ohms/sq. The breakdown voltage of substrate


86


is normally at least 1 volt/μm, preferably more than 4 volt/μm, typically more than 6 volt/μm. Additionally, substrate


86


normally has an average electrical resistivity of 10


8


-10


14


ohm-cm at 25° C. The electrical resistivity of substrate


86


is preferably 10


9


-10


13


ohm-cm at 25° C. In light of this, substrate


86


is typically electrically resistive but may be electrically insulating.




Subject to the preceding considerations on spacer wall constituency and average electrical resistivity, substrate


86


normally consists of ceramic, including glass-like ceramic. Candidates for the ceramic in substrate


86


include all of the materials described above for core substrate


80


and rough layers


82


and


84


. The thickness of primary substrate


86


is normally 10-100 μm, typically 50 μm.





FIGS. 5



c


and


5




d


illustrate two embodiments in which a pair of generally conformal electrically non-insulating coatings


88


and


90


are respectively situated on opposite faces of a primary porous-faced wall-shaped electrically non-conductive body. The term “conformal” here means that coatings


88


and


90


approximately conform to the surface typology of the underlying primary wall and thus approximately replicate its porosity-produced facial roughness. The outside faces of conformal coatings


88


and


90


respectively form rough faces


54


and


56


of main wall


46


. Coatings


88


and


90


normally consist of material whose total natural electron yield coefficient σ is less than coefficient σ of the underlying material of the primary wall. Total natural electron yield coefficient σ of coatings


88


and


90


is normally no more than 2.5, preferably no more than 2.0, more preferably no more than 1.6.




Two effects operate together in the embodiments of

FIGS. 5



c


and


5




d


to reduce the total electron yield that arises when high-energy primary electrons strike conformal coatings


88


and


90


during FED operation. The roughness which is present along the opposite faces of the primary wall in the present FED and which is replicated in the contours of coatings


88


and


90


causes the total electron yield to decrease for the reasons discussed above. The material normally used to form coatings


88


and


90


leads to further reduction in the total electron yield. Total roughness-modified electron yield coefficient σ* in the embodiments of

FIGS. 5



c


and


5




d


is thus lower than coefficient σ* that would arise solely from the roughness in the faces of the primary wall.




The primary wall in

FIG. 5



c


consists of core substrate


80


and overlying rough-faced layers


82


and


84


. Since conformal coatings


88


and


90


are situated respectively on rough layers


82


and


84


, total natural electron yield coefficient σ of coatings


88


and


90


is normally less than coefficient σ of layers


82


and


84


in

FIG. 5



a


. The primary wall in

FIG. 5



d


is formed with primary porous-faced substrate


86


. In

FIG. 5



d


, total natural electron yield coefficient σ of conformal coatings


88


and


90


is less than coefficient σ of substrate


86


. Components


80


,


82


,


84


, and


86


in

FIGS. 5



c


and


5




d


may be formed with any of the materials respectively described above in connection with

FIGS. 5



a


and


5




b


for these main-wall components.




Conformal coatings


88


and


90


typically consist principally of carbon in the form of one or more of amorphous carbon, graphite, and diamond-like carbon. The material, either rough layers


82


and


84


, or rough-faced substrate


86


, that directly underlies coatings


88


and


90


typically consists of oxide of one or more of aluminum, silicon, vanadium, titanium, chromium, iron, tin, and cerium when coatings


88


and


90


are formed primarily with carbon. Alternative or additional candidates for coatings


88


and


90


include oxide of one or more of chromium, cerium, and neodymium.




The thickness of each of conformal coatings


88


and


90


is normally 1-100 nm, typically 5-50 nm. In the embodiment of

FIG. 5



c


, the combination of rough layer


82


and coating


88


or rough layer


84


and coating


90


meets the various sheet resistance, resistance, resistance per unit length, and electrical resistivity specifications given above solely for rough layer


82


or


84


in the embodiment of

FIG. 5



a.






Fabrication of Flat-panel Display, Including Spacer




The present FED is manufactured in the following manner. Backplate structure


20


, faceplate structure


22


, spacer walls


24


, and the peripheral outer wall (not shown) are fabricated separately. Components


20


,


22


, and


24


and the outer wall are then assembled to form the FED in such a way that the pressure in sealed enclosure


26


is at a desired high vacuum level, typically 10


−7


torr or less. During FED assembly, each spacer wall


24


is suitably positioned between plate structures


20


and


22


such that each of rough faces


54


and


56


extends approximately perpendicular to both of plate structures


20


and


22


.




Spacer


24


can be fabricated in a variety of ways. In one general spacer fabrication process, the starting point is a flat structural substrate that serves as a precursor to core substrate


80


in

FIG. 5



a


or


5




c


. The precursor structural substrate is typically large enough for at least four substrates


80


arranged rectangularly in multiple rows and multiple columns. The precursor substrate is bonded along one of its faces to a flat face of a support structure using suitable adhesive. A patterned layer of electrically non-insulating face-electrode material is formed on the other face of the precursor substrate. A blanket protective layer is provided over the patterned face-electrode layer and the exposed portions of the precursor substrate.




Using a suitable cutting device such as a saw, the resulting combination of the precursor substrate, the patterned face-electrode layer, and the protective layer is cut into multiple segments. Each segment of the precursor substrate in the combination constitutes one of core substrates


80


. Although the cuts may extend partway into the support structure, the support structure remains intact. At this point, one or more face electrodes formed from the patterned face-electrode layer are situated on the upper face of each substrate


80


.




A shadow mask is placed above core substrates


80


and the overlying material, including above the segments of the protective layer, at the intended locations for the side edges of substrates


80


, i.e., the substrate edges that extend in the forward (or reverse) electron-travel direction and thus perpendicular to the ends of substrates


80


. With the segments of the protective layer overlying substrates


80


, electrically non-insulating end-electrode material is deposited on the ends of substrates


80


to form end electrodes


50


and


52


on opposite ends of each substrate


80


. The shadow mask prevents the end-electrode material from being deposited on the side edges of substrates


80


. The segments of the protective layer are removed. Substrates


80


, along with the various electrodes, are removed from the support structure by dissolving the remainder of the adhesive.




Porous layers


82


and


84


are subsequently formed on opposite faces of each core substrate


80


to produce main wall


46


of

FIG. 5



a


. Since the patterned face-electrode material is situated on one face of each substrate


80


, either porous layer


82


or porous layer


84


overlies the patterned face-electrode material. If desired, conformal coatings


88


and


90


can be respectively provided along layers


82


and


84


to produce main wall


46


of

FIG. 5



c


. Techniques such as sputtering, evaporation, chemical vapor deposition, and deposition from a liquidous composition, e.g., a solution, colloidal mixture, or slurry, can be employed to form conformal coatings


88


and


90


.




Various modifications can be made to the preceding spacer fabrication process. As one alternative, a pair of rough-faced porous layers that serve as precursors to porous layers


82


and


84


can be respectively provided on the opposite faces of the precursor substrate before the bonding operation at the beginning of the fabrication process. The resulting combination is then bonded along the rough face of one of layers


82


and


84


to the support structure. Subject to this change, further processing is performed as described above. In each final spacer wall


24


, the patterned face-electrode material overlies one of porous layers


82


and


84


. If. conformal coatings


88


and


90


are present, one of them overlies the patterned face-electrode material.




As another alternative, both the formation of the porous precursors to porous layers


82


and


84


and the formation of a pair of conformal coatings that serve as precursors to conformal coatings


88


and


90


can be performed before the bonding operation. The resulting structure at this point appears, in part, as shown in

FIG. 5



c


. The combination of the precursor substrate, the two porous precursor layers, and the two precursor conformal coatings is then bonded along the rough face of one of the precursor coatings to the support structure. Subject to this change, further processing is again conducted as described above. In each final spacer wall


24


, the patterned face-electrode material overlies one of conformal coatings


88


and


90


.




In the first-mentioned alternative, a rough-faced generally wall-shaped substrate that serves as a precursor to rough-faced primary substrate


86


can replace the combination of the precursor to core substrate


80


and the precursors to porous layers


82


and


84


. Main wall


46


in resulting spacer wall


24


therefore appears as shown in

FIG. 5



b


if conformal coatings


88


and


90


are absent or as shown in

FIG. 5



d


if coatings


88


and


90


are present. When coatings


88


and


90


are present, one of them overlies the patterned face-electrode material. This replacement can also be performed in the second-mentioned alternative above. Since coatings


88


and


90


are present in this case, main wall


46


in final spacer wall


24


appears as shown in

FIG. 5



d


, the patterned face-electrode material now overlying one of coatings


88


and


90


.




The patterned face-electrode layer is typically formed by depositing a blanket layer of the desired face-electrode material and selectively removing undesired parts of the face-electrode material using a suitable mask to prevent the face-electrode material from being removed at the intended locations for the face electrodes. Alternatively, the patterned face-electrode layer can be selectively deposited using, for example, a shadow mask to prevent the face-electrode material from accumulating at undesired locations. When the patterned face-electrode material overlies one of conformal coatings


88


and


90


and/or one of porous layers


82


and


84


, use of this alternative avoids possible contamination of wall faces


54


and


56


with material used in forming the face electrodes.




Other modifications can be made to the foregoing spacer fabrication process. For example, the support structure can be eliminated. End electrodes


50


and


52


can be formed in different ways than described above. Instead of cutting the precursor substrate into core substrates


80


and then using a shadow mask to prevent the end-electrode material from being deposited on the side edges of substrates


80


, the precursor substrate and overlying material can be cut into strips that each contain a row (or column) of substrates


80


arranged side edge to side edge. After the end-electrode material is deposited, the strips are then cut into segments that each contain one substrate


80


. In some cases, the formation of end electrodes


50


and


52


and/or the formation of face electrodes such as face electrodes


48


can be eliminated. The spacer fabrication process is then simplified accordingly.




All of the steps involved in the formation of the patterned face-electrode material, end electrodes


50


and


52


, porous layers


82


and


84


, and conformal coatings


88


and


90


, to the extent that these components are present, can be performed directly on each substrate


80


or


86


rather than on a larger precursor to each substrate


80


or


86


. In the general spacer fabrication process first mentioned above and in the variations, the end result is that spacers


24


, each containing at least a segment of material that variously forms substrate


80


or


86


, layers


82


and


84


, when present, and coatings


88


and


90


, when present, are positioned between plate structures


20


and


22


.




Each set of (a)

FIGS. 6



a


-


6




d


, (b)

FIGS. 9



a


,


9




b


, and


10




a


-


10




d


, (c)

FIGS. 9



a


,


9




b


, and


11




a


-


11




d


, (d)

FIGS. 12



a


-


12




d


, (e)

FIGS. 14



a


-


14




c


, (f)

FIGS. 15



a


-


15




c


, and (g)

FIGS. 19



a


-


19




c


(discussed further below) illustrates a process for manufacturing a porous-faced structure suitable for being used partially or fully as main wall


46


in one or more of

FIGS. 5



a


-


5




d


. In each of these processes, material is formed over core substrate


80


or a larger precursor substrate from which two or more of substrates


80


can be made. To simplify the description of these processes, both substrate


80


and the larger precursor substrate are referred to in connection with each of these processes as the “core substrate” and are identified with reference symbol “


80


”.




Fabrication of Porous-faced Structure Suitable for Use in Main Spacer Wall





FIGS. 6



a


-


6




d


(collectively “FIG.


6


”) illustrate a process for manufacturing a porous-faced structure suitable for full or partial use as main spacer wall


46


in

FIG. 5



a


or


5




c


and thus in the flat-panel CRT display of FIG.


1


. When the structure made according to the process of

FIG. 6

is so utilized, the manufacturing steps illustrated in

FIG. 6

are appropriately employed in the above-described processes and process variations for fabricating spacer wall


24


.




The starting point for the process of

FIG. 6

is core substrate


80


. See

FIG. 6



a


. A pair of largely identical thin liquid-containing films


92


are formed on the opposite faces of core substrate


80


.

FIG. 6



b


illustrates one of thin films


92


. Each film


92


consists of precursor material and a liquid interspersed with each other. The precursor material may be in liquid form or solid form, e.g., solid particles. Other material in liquid form, solid form, or/and even gaseous form may be present in films


92


to facilitate or promote the process of FIG.


6


.




Various techniques can be utilized to form thin liquid-containing films


92


on core substrate


80


. For example, portions of a liquid-containing composition of the precursor material and the liquid can be deposited on core substrate


80


. Spinning may be utilized to ensure that each film


92


is of relatively uniform thickness. Alternatively, core substrate


80


can be dipped in the liquid-containing composition.




Thin films


92


can be sprayed on core substrate


80


. A vapor of the liquid-containing composition can be condensed on substrate


80


to create films


92


, especially when the precursor material is in liquid form. Also, films


92


can be electrostatically deposited on substrate


80


. For example, with substrate


80


provided with electric charge of one polarity, an aerosol formed with liquid droplets bearing electric charge of the opposite polarity can be sprayed over substrate


80


. The aerosol droplets may include solid particles. The formation of films


92


can be performed in a homogeneous or heterogeneous manner. Each film


92


may consist of one or more coats.




Thin films


92


are processed in substantially the same way in subsequent steps. For simplicity, only one of films


92


is dealt with in the remainder of the process description for FIG.


6


.




Thin liquid-containing film


92


illustrated in

FIG. 6b

is processed in a manner suitable to convert it into solid porous layer


82


.

FIG. 6



c


depicts the resultant structure. Various techniques, described further below, can be employed to produce porous layer


82


from thin film


92


. Temporarily deferring discussion of the techniques for converting film


92


into layer


82


, the structure in

FIG. 6



c


represents main wall


46


of

FIG. 5



a


if conformal coating


88


is not to be provided over layer


82


. Irregular pores


58


extend into layer


82


along rough face


54


.




If conformal coating


88


is to be provided over porous layer


82


, layer


82


has a rough face


94


along which there are irregular pores


96


. Upon forming coating


88


on rough face


94


, the structure appears as shown in

FIG. 6



d


. This structure represents main wall


46


of

FIG. 5



c


. Coating


88


extends into pores


96


along rough face


54


. Pores


96


, including those partially filled with coating


88


, respectively become pores


58


.




Turning now to the techniques for converting thin liquid-containing film


92


into solid porous layer


82


, thin film


92


is typically first transformed into a gel, i.e., a semi-solid structure, or a liquid-filled open network of solid material, dependent on the nature of the precursor material in film


92


. The liquid is then largely removed from the gel or open network of solid material to create layer


82


. The transformation of film


92


into layer


82


is performed generally according to the porous-ceramic preparation techniques described in Saggio-Woyansky et al, “Processing of Porous Ceramics,”


Technology


, November 1992, pages 1674-1682, or the sol-gel techniques described in Hench et al, “The Sol-Gel Process,”


Chem. Rev


., Vol. 90, No. 1, pages 33-72, and Brinker et al, “Sol-Gel Thin Film Formation,”


J. Cer. Soc. Japan, Cent. Mem. Iss


., Vol. 99, No. 10, 1991, pages 862-877. The contents of Saggio-Woyansky et al, Hench et al, and Brinker et al are incorporated by reference herein.




In the case of a gel, the precursor material in thin film


92


is typically formed with a ceramic precursor that contains desired ceramic cation species. More particularly, the ceramic precursor is normally metalorganic polymeric material, where the Group 4a cation species silicon and germanium, although generally considered to be semiconductors, are here viewed as metals. Using a sol-gel procedure, the ceramic precursor is converted by polymerization into support material whose shape largely defines the shape of the gel. Liquid is distributed largely throughout the gel.




The ceramic precursor typically consists of alkoxide of one or more metals and metal-like elements. As the alkoxide precursor undergoes polymerization, atoms of the precursor cross-link to form the gel support material principally as metallic oxide. Metallic hydroxide may also be present in the gel support material.




The metallic cations in the ceramic Precursor for the gel consist of one or more non-carbon elements in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, including the lanthanides. Particularly attractive ceramic cation candidates are silicon, titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten. Two or more of these cation candidates may be present in the ceramic precursor, typically in mixed form. Except for silicon, germanium, and tin, all of the particularly attractive candidates for the ceramic cations are transition metals. In one implementation, the metallic cations in the ceramic precursor consist principally of silicon.




The ceramic precursor to the support material in the gel may be monomeric, partially hydrolyzed, and/or oligomeric. Other types of ceramic precursor material may be employed in place of, or in combination with, alkoxide precursor. Examples of alternative ceramic precursors that have silicon cations include alkoxysilanes, alkylalkoxysilanes, acetoxysilanes, chlorosilanes and alkylchlorosilanes. In any event, the gel is largely centered around bonds between oxygen and the metallic cations of the ceramic precursor. Hydroxyl (OH) groups may also be present, especially along the pore surfaces.




The liquid used in thin film


92


to form the polymeric gel is normally an organic solvent. Examples of the organic solvent include alcohols such as ethanol and isopropanol, ketones such as acetone and methylisobutylketone, and polyols such as ethylene glycol. Other organic liquids in which the ceramic precursor is miscible may also be used for the organic solvent. Additional liquid is typically produced in the gel as a byproduct of the gel processing. The rate at which the gel forms is determined by pH, temperature, water content, precursor reactivity, and evaporation rate. One or more catalysts may be employed to control the gel reaction polymerization rate.




Rather than being polymeric, the precursor material in thin liquid-containing film


92


may consist of ceramic precursor particles distributed largely throughout thin film


92


. The conversion of film


92


into porous layer


82


then entails going through an intermediate stage of a gel or a liquid-filled open network of solid material. In the case of a liquid-filled open solid network, the ceramic precursor particles are converted into solid support material whose shape defines the shape of the open solid network. A similar phenomenon occurs in the gel case except that the support material produced from the ceramic precursor material is semi-solid rather than solid. Liquid occupies interstices in the gel or open solid network.




Candidates for the ceramic precursor particles are oxides, hydroxides, carbides, carbonates, nitrides, nitrates, phosphides, phosphates, sulfides, sulfates, chlorides, chlorates, acetates, citrates, and oxalates of one or more metals and metal-like elements. The precursor particles may include two or more of these anion species. Particularly attractive anion species for the precursor particles are oxides, hydroxides, carbonates, nitrates, sulfates, acetates, citrates, and oxalates.




Candidates for the metallic cations in the ceramic precursor particles are non-carbon elements in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, including the lanthanides. Particularly attractive cation candidates for the precursor particles are silicon, titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten. The precursor particles may have two or more of these cation elements, typically in mixed form. Once again, except for silicon, germanium, and tin, all of the particularly attractive cation candidates are transition metals. In a typical implementation, the ceramic particles consist of oxide, hydroxide, and/or nitrate of chromium. The average diameter of the ceramic particles is normally 1-500 nm, preferably 2-100 nm.




When the precursor material consists of ceramic precursor particles, the liquid in thin film


92


typically consists of water. The ceramic precursor particles normally become suspended in the water or other liquid. The liquid may contain surface-active agents for reducing surface tension and increasing storage stability. Storage stability may also be increased by including dilute acids or bases in the liquid.




The precursor material may be formed with both polymeric ceramic material and ceramic precursor particles. Regardless of whether the precursor material consists of polymeric ceramic material or ceramic precursor particles or both, liquid is normally removed from the gel or liquid-filled open solid network without causing the support material to fully collapse and fill the space previously occupied by the liquid. The gel or open solid network thereby becomes a solid porous layer. The liquid removal is typically conducted by drying the gel or open solid network at approximately room temperature, i.e., approximately 25° C. When a polymeric ceramic precursor is utilized to form the support material in film


92


, further cross-linking may occur during the liquid removal.




Heat is typically applied to the solid porous layer. The heat causes atoms of the precursor material to bond to one another. In particular, the heat causes further cross-linking when the precursor material is polymeric. Additional bonds between oxygen and the metallic cations are formed. When the precursor material consists of particles, the heat causes bonds to form between oxygen and the metallic cations in the particles. The heat also causes bonds to form between oxygen and metallic cations located between the particles. Inasmuch as heat causes the solid porous layer to densify and become less porous, the heat treatment is conducted in such a manner that the porosity does not become unacceptably low.





FIG. 6



c


illustrates the structure at the end of liquid removal and heat treatment. The solid porous layer created from liquid-containing thin film


92


is now porous layer


82


. When the precursor material is polymeric, porous layer


82


consists largely of oxide and/or hydroxide of one or more of the metallic cations identified above for the ceramic precursor. When ceramic precursor particles are used in creating film


92


, porous layer


82


contains much of the metallic ions that were present in the particles. However, even if no metallic oxide and/or hydroxide was initially present in the ceramic precursor particles, the heat treatment normally causes some oxide and/or hydroxide to form with the metallic cations in the particles.




In a variation of the procedure for converting thin liquid-containing film


92


into solid porous layer


82


, the precursor material and the liquid in thin film


92


can be of such a nature that the porosity in solid layer


82


occurs at least partly due to gas produced during the processing steps. For example, water vapor and/or volatile decomposition products such as carbon dioxide and sulfur dioxide can be produced by decomposition from part of the precursor material and/or the liquid in film


92


. As a solid porous layer is created from the gel or open solid network, the evolution of gas causes the porosity to increase and, with suitable control, appropriately counters any tendency of the solid porous layer to shrink.




An alternative technique for producing porous layer


82


from thin film


92


entails using sacrificial carbon-containing, normally organic, material to create or enhance porosity. The sacrificial carbon-containing material is part of the precursor material in thin film


92


. The remaining precursor material, referred to here as the main precursor material, can be polymeric, typically inorganic, and/or can consist of ceramic precursor particles. In either case, the sacrificial carbon-containing material can be bonded to the metallic cations in the main precursor material or/and can be added in separate form, such as particles, to thin film


92


. When the sacrificial material is distinct from the main precursor material, the two parts of the precursor material can be introduced into the liquid-containing composition later used to form thin film


92


. The sacrificial material can also be (a) provided on substrate


80


before film


92


is provided and over substrate


80


or (b) introduced into film


92


after it is otherwise provided on core substrate


80


.




Subject to incorporating the sacrificial carbon-containing material into thin film


92


, the processing of film


92


can be conducted according to the sol-gel or porous-ceramic techniques described above to produce an intermediate solid porous film which is basically the same as porous layer


82


except that the intermediate solid porous layer contains the sacrificial material. Layer


82


is then created by partially or substantially removing the sacrificial material from the intermediate solid film.




Pyrolysis, oxidation, or/and evaporation can be employed to partially or substantially remove the sacrificial carbon-containing material from the intermediate solid film. Both carbon and non-carbon portions of the sacrificial material are normally removed. Pyrolysis is typically performed at 200-900° C., preferably 400-600° C., in an oxidizing environment. When the intermediate solid film is quite thin, e.g., the film thickness is in the vicinity of 1 μm or less, the pyrolysis temperature can normally be readily reduced to as little as 250° C. The partial or substantial removal of the sacrificial material can alternatively or additionally be performed by subjecting the sacrificial material to a plasma, an electron beam, ultraviolet light, a suitable oxidizing environment, or/and a suitable reducing environment.




Alternatively, the process operations involving the sacrificial carbon-containing material can be conducted in the foregoing way except that the intermediate solid porous layer created from the gel or open solid network is heat treated to such an extent that the porosity largely goes to zero. Porous layer


82


is then created by partially or substantially removing the sacrificial material from the intermediate porous film. In effect, porosity is re-introduced into layer


82


. Again, both carbon and non-carbon portions of the sacrificial material are normally removed. The partial or substantial removal of the sacrificial material is performed in the manner described above. Creating layer


82


by this porosity re-introduction procedure is advantageous because the pore size and uniformity can be controlled well. Also, the mechanical strength of final main wall


46


is typically increased.




In another alternative, thin liquid-containing film


92


can be converted into an intermediate solid film having little, if any, porosity according to a procedure that does not entail going through a solid porous stage while the sacrificial carbon-containing material is present. For example, a dense intermediate solid film that contains the sacrificial material and metallic oxide and/or hydroxide can be created directly from film


92


. The sacrificial material is then partially or substantially removed from the intermediate solid film to convert it into porous layer


82


. Once again, both carbon and non-carbon components of the sacrificial material are normally removed. The partial or substantial removal of the sacrificial material is conducted as described above. Similar to what was said about the previous alternative, creating layer


82


according to this alternative enables the pore size and uniformity to be controlled well. Likewise final main wall


46


is of increased mechanical strength when layer


82


is created according to this alternative.




When the processing operations that involve the sacrificial carbon-containing material are conducted in the preceding manner, the resultant structure appears generally as shown in

FIG. 6



c


. As a further alternative, the partial or substantial removal of the sacrificial material can be replaced with a step in which largely only the non-carbon part of the sacrificial material is largely removed. With suitable control, the carbon remainder of the sacrificial material forms a carbon coating that lies along the surfaces of the pores created by the removal of the non-carbon material. The resulting structure implements

FIG. 6



d


in which conformal coating


88


consists principally of the remaining carbon material. A further desciption of this process is presented below in connection with

FIGS. 14



a


-


14




c.






Part or all of the structure of

FIG. 6



c


or


6




d


is, as indicated above, suitable for main spacer wall


46


. Nonetheless, the structure of

FIG. 6



c


or


6




d


can be utilized for other purposes. For instance, the structure of

FIG. 6



c


or


6




d


can be employed as a catalyst or in a chemical gas sensor of high surface area.




Main Spacer Wall Having Porous Layer Constituted With Aggregates of Particles





FIG. 7

depicts an embodiment of a portion of main spacer wall


46


along rough face


54


, and an adjoining portion of faceplate structure


22


. The embodiment of

FIG. 7

implements the structure of

FIG. 5



c


for the situation in which composite porous layer


82


and conformal coating


88


form a porous body consisting of fractal aggregates


100


bonded to one another. At the scale used in

FIG. 7

, coating


88


is too thin to be clearly distinguished from layer


82


and, except for the reference symbol


82


/


88


, is not specifically illustrated. Pores


58


are located between adjoining ones of fractal aggregates


100


so as to achieve the porosity characteristics prescribed above.




Each fractal aggregate


100


is formed with multiple particles


102


bonded to one another. The number of particles


102


in each aggregate


100


typically varies from as little as 2 to as many as 1,000 or more. Particles


102


are typically roughly spherical. As a result, pores which are considerably smaller than pores


58


are present between adjoining ones of coated particles


102


. The average diameter of particles


102


is 1-1,000 nm, preferably 5-200 nm.




Each particle


102


normally consists of a support particle and a particle coating that overlies part or all of the support particle. When particles


102


are so configured, they are often referred to as coated particles. The support particles in coated particles


102


are normally electrically non-conductive, i.e., the support particles consist of electrically insulating or/and electrically resistive material. The particle coatings likewise are normally electrically non-conductive.





FIGS. 8



a


and


8




b


present two implementations of fractal aggregates


100


in which each coated particle


102


is formed with a support particle and an overlying particle coating. In both implementations, the average value of total natural electron yield coefficient σ for the particle coatings is normally less than the average value of coefficient σ for the support particles. The number of secondary electrons emitted by coated particles


102


when they are struck by high-energy primary electrons is thus lower than what would occur with aggregates formed solely with the support particles, i.e., without using the particle coatings. As described further below, a portion of the material of the particle coatings forms conformal coating


88


so that the structure of

FIG. 7

implements main wall


46


of

FIG. 5



c.






In

FIG. 8



a


, each coated particle


102


consists of a support particle


104


and a coating


106


that overlies part of particle


104


. The bonding of coated particles


102


to one another in fractal aggregate


100


of

FIG. 8



a


occurs along the outer surfaces of support particles


104


to such an extent that support particles


104


themselves form a bonded fractal support-particle aggregate. Particle coatings


106


increase the strength of the bonding of coated particles


102


in each fractal aggregate


100


. The average thickness of particle coatings


106


is 0.2-100 nm, typically 10 nm.




Although not shown in

FIG. 8



a


, each fractal aggregate


100


may include some support particles


104


which are largely internal to that aggregate


100


and which, while possible touching coated particles


102


, are largely uncoated. That is, these internal support particles


104


lack particle coatings


106


. The occurrence of totally uncoated support particles


104


occurs due to the way, discussed further below, in which aggregates


100


are formed to produce the structure of

FIG. 8



a


. Since any uncoated support particles


104


are internal to each aggregate


100


, the presence of uncoated support particles


104


does not have any significant effect on FED operation.




In

FIG. 8



b


, each coated particle


102


is formed with a support particle


104


and a coating


108


that largely wholly overlies that particle


104


. The bonding of coated particles


102


to one another in fractal aggregate


100


of

FIG. 8



b


occurs along the outer surfaces of particle coatings


108


. In some cases, the bonding may penetrate through coatings


108


so that two or more of coated particles


102


are bonded together along their support particles


104


. As with coatings


106


in

FIG. 8



a


, the average thickness of coatings


108


in

FIG. 8



b


is 0.2-100 nm, typically 10 nm.




Support particles


104


normally consist of oxide or/and hydroxide of one or more metals and metal-like elements. Specifically, candidate materials for support particles


104


are oxides and hydroxides of one or more non-carbon elements in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, including the lanthanides. Particularly attractive oxides and hydroxides that can be utilized for support particles


104


are those of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium, including oxide and/or hydroxide of two or more of these elements, typically in mixed form. Except for aluminum and silicon, all of the particularly attractive support oxide/hydroxide candidates are oxides and hydroxides of transition metals.




Candidates for the material of particle coatings


106


or


108


consist of oxides and hydroxides of one or more of titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten. Especially attractive oxides and hydroxides that can be utilized for coatings


106


or


108


are those of titanium, chromium, manganese, iron, zirconium, cerium, and neodymium, including oxide and/or hydroxide of two or more of these metals, typically in mixed form. All of the oxides and hydroxides especially attractive for coatings


106


and


108


are oxides and hydroxides of transition metals. Coatings


106


or


108


are normally, but not necessarily, of different chemical composition than support particles


104


. Subject to this, coatings


106


or


108


typically consist of one or more of these especially attractive oxides and hydroxides when support particles


104


consist of oxide and/or hydroxide of one or more of aluminum, silicon, chromium, titanium, iron, zirconium, cerium, and neodymium. Coatings


106


or


108


may alternatively or additionally include carbon.




Porous layer


82


consisting of fractal aggregates


100


can be fabricated in various ways so that each aggregate


100


appears largely as depicted in

FIG. 8



a


or


8




b


.

FIGS. 9



a


and


9




b


(collectively “FIG.


9


”) depict an initial pair of steps in a process for manufacturing a structure that contains spacer wall


24


in which layer


82


is formed with aggregates


100


as depicted in

FIG. 8



a


. The fabrication of a structure in which layer


82


consists of aggregates


100


as shown in

FIG. 8



a


can be continued according to the process sequence of

FIGS. 10



a


-


10




d


(collectively “FIG.


10


”), discussed further below, or according to the process sequence of

FIGS. 11



a


-


11




d


(collectively “FIG.


11


”), also discussed further below.




The front-end process sequence of

FIG. 9

begins with a liquidous colloidal composition


110


provided in a container


112


. See

FIG. 9



a


. Colloidal composition


110


consists of support particles


104


and a suitable liquid in which support particles


104


are dispersed. Should support particles


104


have a tendency to precipitate and accumulate on the bottom of container


112


, an appropriate additive can be mixed into composition


110


to prevent particles


104


from precipitating. Alternatively or additionally, container


112


can be appropriately agitated to disperse particles


104


into the bulk of the liquid.




The liquid in colloidal composition


110


is formed with a principal constituent and possible one or more additives. As discussed further below, groups of support particles


104


are induced to come together and form separate fractal aggregates of particles


104


in the liquid. The characteristics of the principal constituent and any additive are of such a nature that support particles


104


form aggregates in a suitably short time period. The principal constituent, which is typically a volume-fraction majority of the liquid, is water or/and an organic solvent with a boiling point of 50-200° C. at 1 atmosphere. When support particles


104


consist of oxide and/or hydroxide of one or more of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium, the principal constituent is typically water or an alcohol, such as ethanol or isopropanol, whose 1-atm boiling point is 50-200° C. Additive material in the liquid provides various capabilities such as accelerating aggregation and promoting bonding of support particles


104


to one another.




With the composition and characteristics of support particles


104


and the liquid being appropriately chosen, particles


104


are induced to bond together in separate groups to form fractal support-particle aggregates


114


. See

FIG. 9



b


. Various techniques can be employed to promote the aggregation of particles


104


into support-particle aggregates


114


. For example, heat can be applied to colloidal composition


110


. Changes in pH, implemented with one or more additives such as an acid or a base, can be utilized to promote the particle aggregation. The aggregation can also be promoted by changing the ionic strength of composition


110


.




In the example of

FIG. 9



b


, the aggregation of particles


104


to form support-particle aggregates


114


occurs while colloidal composition


110


is in container


112


. If support-particle aggregates


114


tend to precipitate and form a single large aggregate along the bottom of container


112


, container


112


can be suitable agitated to avoid precipitation at this stage. As discussed further below, the aggregation of particles


104


can partially or totally occur after one or more portions of composition


110


are provided on a suitable substrate.




Turning to the back-end process sequence of

FIG. 10

, a pair of largely identical portions


116


of colloidal composition


110


are provided on the opposite faces of core substrate


80


.

FIG. 10



a


depicts one of portions


116


. Each portion


116


is a relatively thin liquidous colloidal film-like body in which support particles


104


are dispersed at a relatively uniform concentration. The film thickness is 10 nm-10 μm, typically 100 nm-1 μm




Colloidal films


116


can be formed over core substrate


80


in various ways such as dipping substrate


80


in colloidal composition


110


, spraying films


116


over substrate


80


, depositing portions of composition


110


on the opposite faces of substrate


80


and, as necessary, spinning the deposited portions to form each film


116


at a relatively uniform thickness. As indicated above, the aggregation of support particles


104


to form aggregates


114


can partially or totally occur after films


116


are provided on substrate


80


.




Colloidal films


116


are processed substantially the same in subsequent steps. For simplicity only one of films


116


is dealt with in the remainder of the process description for FIG.


10


.




Fractal support-particle aggregates


114


in illustrated colloidal film


116


are caused to bond together in an open manner to form a solid film-like porous body


118


as shown in

FIG. 10



b


. Irregular pores


120


extend between bonded support-particle aggregates


114


in solid porous film


118


. Heat can be applied to promote the bonding of support-particle aggregates


114


to one another. Changes in the pH and/or ionic strength of colloidal composition


100


, the precursor to colloidal film


116


, can be utilized to promote the aggregate bonding action. The liquid in film


116


is also removed. The liquid removal can be performed by drying film


116


at approximately room temperature and/or by applying heat. The bonding of support-particle aggregates


114


to form solid film


118


may occur during and/or before the liquid removal.




Material


122


, which constitutes a precursor to particle coatings


106


, is formed over support particles


104


in bonded fractal support-particle aggregates


114


of porous film


118


. See

FIG. 10



c


. Although not evident in

FIG. 10



c


, precursor material


122


typically covers portions of support particles


104


that are internal to bonded aggregates


114


in a manner similar to that shown in

FIG. 8



a


for particles coatings


106


.




When particle coatings


106


are to consist of oxide or/and hydroxide of one or more of (a) titanium, (b) chromium, (c) manganese, (d) iron, (e) zirconium, (f) cerium, and (g) neodymium, candidates for precursor material


122


respectively are (a) ethoxide or/and isopropoxide of titanium, (b) carbonate, chloride, hydroxide, nitrate, or/and sulfate of chromium, (c) carbonate, chloride, hydroxide, nitrate, or/and sulfate of manganese, (d) carbonate, chloride, hydroxide, nitrate, or/and sulfate of iron, (e) butoxide, carbonate, chloride, ethoxide, hydroxide, isopropoxide, nitrate, or/and sulfate of zirconium, (f) ammonium cerium nitrate or/and carbonate, chloride, hydroxide, nitrate, or/and sulfate of cerium, and (g) acetate, carbonate, chloride, hydroxide, nitrate, or/and sulfate of neodymium. If precursor material


122


contains hydroxide of chromium, manganese, iron, zirconium, cerium, or/and neodymium, the hydroxide is typically converted into oxide in particle coatings


106


. Although precursor material


122


is typically a salt, material


122


can be polymeric. In some cases, material


122


is metalorganic or/and organometallic.




Precursor material


122


can be formed over support particles


104


of solid porous film


118


in various ways. One technique is to prepare a liquidous composition of a basic particle-coating precursor and a suitable liquid. The particle-coating precursor, which contains the material that constitutes precursor material


122


, may be dissolved or dispersed in the liquid. A thin-film portion of the liquidous composition is provided over support particles


104


in porous film


118


. This can be accomplished by dipping the structure of

FIG. 10



b


into the liquidous composition, spraying a very thin film of the liquidous composition on porous film


118


, using a deposition/spinning technique to form a very thin liquidous film on porous film


118


, condensing a portion of a vapor of the liquidous composition on porous film


118


, or electrostatically depositing a thin film of the liquidous composition on porous film


118


. In any event, the liquid is removed from the thin precursor-material film so that precursor material


122


coats support particles


104


.




Alternatively, precursor material


122


can be directly deposited on support particles


104


of porous film


118


. One candidate direct deposition technique is coprecipation. Another is heterocoagulation.




An operation is performed that causes precursor material


122


to be converted into particle coatings


106


.

FIG. 10



d


depicts the resultant structure in which support-particle aggregates


114


have become fractal aggregates


100


of coated particles


102


, coated porous film


118


has become porous layer


82


, pores


120


have become pores


58


, and the portion of precursor material


122


along rough face


54


has become conformal coating


88


. Each fractal aggregate


100


of composite porous body


82


/


88


in

FIG. 10



d


appears as shown in

FIG. 8



a.






The conversion of precursor material


122


into particle coatings


106


is typically achieved by heating material


122


. Alternatively or additionally and also dependent on the particular characteristics of precursor material


122


, water or/and changes in pH can be utilized to convert material


122


into coatings


106


. When material


122


is formed by removing liquid from a thin liquidous film that contains the basic particle-coating precursor, the liquid removal can be done partially or fully at the same time as the heating operation. Also, a non-heating conversion technique can be performed while material


122


is simply dried at approximately room temperature.




The process sequence of

FIG. 10

can be modified in various ways. As one variation, particle coatings


106


can be formed directly on support particles


104


after support-particle aggregates


114


have bonded together to form solid porous film


118


. That is, no precursor to particle coatings


106


is utilized. With the stage shown in

FIG. 10



c


thereby having been eliminated, the process sequence jumps from the stage of

FIG. 10



b


to the stage of

FIG. 10



d.






The back-end process sequence of

FIG. 11

is another variation of the process sequence of FIG.


10


. In the back-end sequence of

FIG. 11

, precursor material


122


is formed over support particles


104


of fractal support-particle aggregates


114


while aggregates


114


are still in colloidal composition


110


. See

FIG. 11



a


. This operation can be implemented by introducing the desired basic particle-coating precursor into composition


110


after aggregates


114


have been formed.




A pair of largely identical portions


124


of so-modified colloidal composition


110


are provided on the opposite faces of core substrate


80


.

FIG. 11



b


shows one of portions


124


. Each portion


124


is a relatively thin liquidous colloidal film-like body having largely the same characteristics as each colloidal film


116


except that precursor material


122


covers support particles


104


of each aggregate


114


in each colloidal film


124


. Any of the techniques utilized to form films


116


in the process sequence of

FIG. 10

can be employed to form films


124


in the process sequence of FIG.


11


.




Colloidal films


124


are processed in substantially the same way in later operations. Only one of films


124


is, for simplicity, dealt with in the remainder of the process description for FIG.


11


.




Particle aggregates


114


, as coated with precursor material


122


in illustrated colloidal film


124


, are now caused to bond together in an open manner to form a solid film-like porous body


126


as shown in

FIG. 11



c


. Irregular pores


128


extend between precursor-coated bonded aggregates


114


. Similar to the process sequence of

FIG. 10

, heat can be applied to promote the bonding of precursor-coated particle aggregates


114


to one another. The aggregate bonding action can also be promoted through changes in the pH and/or ionic strength of precursor-containing colloidal composition


110


, the precursor to colloidal film


124


. The liquid in colloidal film


124


is also removed. The liquid removal can be performed by drying the structure of

FIG. 11



b


at approximately room temperature. Heat can alternatively or additionally be used to remove the liquid provided that the heat does not cause precursor material


122


to change chemical form in an undesired way.




Precursor material


122


in the process sequence of

FIG. 11

is now converted into particle coatings


106


. See

FIG. 11



d


in which precursor-coated support particle aggregates


114


have again become fractal coated-particle aggregates


100


, coated solid porous film


126


has become solid porous layer


82


, pores


128


have become pores


58


, and the portion of the particle coating material along rough face


54


has again become conformal coating


88


. The conversion of precursor material


122


into particle coatings


106


is typically achieved by heating material


122


. The heating step is performed in the way prescribed above for the process sequence of FIG.


10


.




Porous layer


82


in

FIG. 11



d


is very similar to porous layer


82


in

FIG. 10



d


. The only notable difference is that the bonding of support-particle aggregates


114


to one another in

FIG. 11



d


may occur through particle coatings


106


because precursor material


122


in the process sequence of

FIG. 11

is formed over support-particle aggregates


114


before they have bonded together rather than after they have bonded together as occurs in the process sequence of FIG.


10


. Each fractal aggregate


100


of porous body


82


/


88


in

FIG. 11



d


appears largely as depicted in

FIG. 8



a.






The process sequence of

FIG. 11

can be modified in various ways. As one variation, the removal of the liquid in colloidal composition


124


and the conversion of precursor material


122


into particle coatings


106


can be performed partially or fully simultaneously. The stage of

FIG. 11



c


may then be deleted. As another variation, the basic particle-coating precursor, or a catalyst that causes the basic particle-coating precursor to accumulate over support particles


104


, can be supplied directly to colloidal film


124


rather than to composition


110


. In this case, the formation of precursor material


122


on support particles


104


and the bonding of support-particle aggregates


114


to form solid porous film


126


may occur partially or fully simultaneously.





FIGS. 12



a


-


12




d


(collectively “FIG.


12


”) depict a process for manufacturing a structure such as main wall


46


in which composite porous body


82


/


88


is formed with fractal aggregates


100


of the type depicted in

FIG. 8



b


. The process of

FIG. 12

begins with a liquidous colloidal composition


130


provided in container


112


. See

FIG. 12



a


. Colloidal composition


130


consists of coated particles


102


and a suitable liquid in which particles


102


are suspended. As

FIG. 12



a


indicates, each coated particle


102


here consists of support particle


104


and particle coating


108


. Any tendency that coated particles may have to precipitate and accumulate on the bottom of container


112


can be inhibited by mixing a suitable additive into composition


130


or/and appropriately agitating container


112


.




Various techniques can be employed to form particle coatings


108


over support particles


104


in one or more processing steps that precede the stage shown in

FIG. 12



a


. For example, support particles


104


and the material intended to form particle coatings


108


can be combined with a liquid. By appropriately choosing support particles


104


, the particle coating material, and the liquid, the coating material accumulates over support particles


104


to form coated particles


102


. As the coating material accumulates over support particles


104


, chemical reactions may occur to strengthen bonding of particle coatings


108


to support particles


104


. One or more suitable additives can be mixed into the liquid to promote the coating action. Changes in the pH and/or ionic strength of the liquid can also be utilized to promote the coating action. The liquid may be the liquid of colloidal composition


130


. If not, coated particles


102


are subsequently transferred to the liquid of composition


130


.




Alternatively, support particles


104


and a basic precursor to the particle-coating material can be combined with a liquid to form a liquidous colloidal composition. The basic particle-coating precursor accumulates over support particles


104


and undergoes suitable bonding that converts the particle-coating precursor into particle coatings


108


. The conversion of the particle-coating precursor into coatings


108


can be initiated or promoted by heating the colloidal composition. One or more additives can be introduced into the colloidal composition to promote the coating formation. Changes in the pH and/or ionic strength of the colloidal composition can also be employed to promote the coating formation. If the liquid is not the liquid of colloidal composition


130


, coated particles


102


can be subsequently transferred to the liquid of composition


130


.




Having reached the stage of

FIG. 12



a


, coated particles


102


are induced to bond together in groups to form fractal coated-particle aggregates


100


in colloidal composition


130


.

FIG. 12



b


illustrates this stage. The aggregation of coated particles


102


to form aggregates


100


can be promoted in various ways. For example, heat can be applied to composition


130


. The particle aggregation can also be promoted through changes in the pH and/or ionic strength of composition


130


.




A pair of largely identical portions


132


of colloidal composition


130


are provided on the opposite faces of core substrate.

FIG. 12



c


depicts one of portions


132


. Each of portions


132


is a relatively thin liquidous colloidal film-like body having largely the same characteristics as each of colloidal films


116


described above, except that particle coatings


108


overlie support particles


104


of aggregates


100


in each colloidal film


132


. Any of the techniques utilized to form films


116


in the process sequence of

FIG. 10

can be utilized to form films


132


in the process of FIG.


12


.




In subsequent operations, colloidal films


132


are processed substantially the same. For simplicity, only one of films


132


is dealt with in the remainder of the process description for FIG.


12


.




Coated-particle aggregates


100


in illustrated colloidal film


132


are now caused to bond together in an open manner to form solid porous layer


82


as shown in

FIG. 12



d


. The aggregate bonding action can be promoted by employing any of the aggregate bonding techniques described above for the process sequences of

FIGS. 10 and 11

. The liquid in thin film


132


is also removed. The liquid removal can be performed by drying film


132


at approximately room temperature. Alternatively or additionally, heat can be employed in removing the liquid. The portion of the particle coating material along rough face


54


forms conformal coating


88


. Each coated-particle aggregate


100


in

FIG. 12



d


appears as shown in

FIG. 8



b.






The process of

FIG. 12

can be modified in a variety of ways. The formation of particle coatings


108


on support particles


104


and the aggregation of coated particles


102


to form fractal aggregates


100


can occur partially or fully simultaneously. The aggregation of coated particles


102


to form aggregates


100


can occur partially or fully in colloidal film


132


rather than totally in colloidal composition


130


.




As indicated above, item


80


(a) in the process of

FIG. 12

, (b) in the composite process of

FIGS. 9 and 11

, (c) in the composite process of

FIGS. 9 and 10

, and (d) in the variations of these processes represents both core substrate


80


of spacer wall


24


and a larger precursor substrate from which two or more of substrates


80


can be made. When item


80


in these processes and process variations represents core substrate


80


, the structure in each of

FIGS. 10



d


,


11




d


, and


12




d


implements main wall


46


. When item


80


in these processes and process variations represents the larger precursor substrate, the structure in each of

FIGS. 10



d


,


11




d


, and


12




d


can be cut into multiple portions to form multiple walls


46


. In either case, the formation of electrodes


48


,


50


, and


52


along each wall


46


fabricated according to any of these processes and process variations is integrated with each of these processes and process variations in the manner prescribed above.




Particles


102


in fractal particle aggregates


100


may consist principally of uncoated particles, i.e., particles not having particle coatings that overlie generally distinct support particles, in another implementation of main wall


46


. More particularly, aggregates


100


can be formed principally with uncoated particles when total roughness modified electron yield coefficient σ* is sufficiently low for such aggregates


100


. The uncoated particles of aggregates


100


may, for example, be constituted largely the same as support particles


104


.




The fabrication of the present flat-panel display, including spacer walls


24


, in the uncoated particle variation is conducted in the manner described above for the coated-particle embodiments except that the steps involved in forming particle coatings over support particles are omitted. In the revised fabrication process, suitable uncoated particles are induced to bond together in groups to form respective fractal aggregates


100


of uncoated particles. Fractal aggregates


100


are then caused to bond together in an open manner over core substrate


80


to form layer-shaped porous body


82


. The resultant structure is then utilized in one or more of main walls


46


.




While the structure of each of

FIGS. 10



d


,


11




d


, and


12




d


is particularly suitable for partial or full use in spacer wall


24


, each of these structures can be employed in other applications. As an example, the structure of

FIG. 10



d


,


11




d


, or


12




d


can be utilized as a catalyst or in a high-surface-area chemical gas sensor. The same occurs when fractal aggregates


100


are principally formed with uncoated particles.




Main Spacer Wall Having Carbon-Containing Coating





FIG. 13

illustrates another embodiment of a portion of main spacer wall


46


along rough face


54


, and an adjoining portion of faceplate structure


22


. The embodiment of

FIG. 13

implements the structure of

FIG. 5



c


for the situation in which conformal coating


88


consists principally of carbon. Hence, carbon-containing coating


88


is normally of lower total natural electron yield coefficient a than underlying porous layer


82


. Coating


88


in

FIG. 13

is part of a multi-part carbon-containing coating


140


that defines (a) the pore surfaces along coating


88


and (b) the surfaces of pores


58


situated fully below face


54


.




More particularly, irregular primary pores


142


are randomly distributed throughout porous layer


82


in FIG.


13


. Some of primary pores


142


are situated along rough face


54


and thus are externally accessible. Others of pores


142


are fully enclosed by the porous body formed with core substrate


80


, porous layer


82


, and porous layer


84


(not shown), and thus are externally inaccessible. The average diameter of primary pores


142


is normally 5-1,000 nm, preferably 5-200 nm.




Carbon-containing coating


140


overlies the surfaces of substantially all of primary pores


142


, including those that are externally inaccessible, thereby respectively converting pores


142


into pores


58


, referred to here as further pores. Conformal coating


88


consists of the portion of carbon-containing coating


140


situated along the externally accessible ones of primary pores


142


. Due to the presence of coating


140


, the average diameter of further pores


58


is less than the average diameter of primary pores


142


. The minimum average diameter of further pores


58


is typically 1 nm. Depending on the thickness of coating


140


, the maximum average diameter of further pores


58


is typically in the vicinity of 1,000 nm, preferably in the vicinity of 200 nm. Porous layer


82


in

FIG. 13

has the above-described porosity characteristics. Hence, the minimum porosity along layer


82


is normally at least 10%.




Carbon-containing coating


140


, including conformal coating


88


, is normally more than 50% carbon. The percentage of carbon in coating


140


is typically at least 80%. The carbon in coating


140


is normally substantially all amorphous carbon. Alternatively, coating


140


may consist substantially of diamond-like carbon or a combination of amorphous carbon and diamond-like carbon.




Carbon-containing coating


140


normally has a thickness of 1-100 nm, preferably 5-50 nm. The thickness of coating


140


is normally highly uniform. The standard deviation in the thickness of coating


140


is normally no more than 20%, preferably no more than 10%, of the average coating thickness. By achieving this thickness uniformity, coating


140


can be made quite thin without exposing a significant portion of porous layer


82


and thus increasing the secondary electron emission from main wall


46


due to fact that layer


82


is normally of higher total natural electron yield coefficient σ than coating


140


. In turn, making coating


140


thin reduces the power dissipation in main wall


46


.





FIGS. 14



a


-


14




c


(collectively “FIG.


14


”) depict a process for manufacturing a structure such as main wall


46


in which conformal coating


88


is part of carbon-containing coating


140


. The starting point for the process of

FIG. 14

is a substructure consisting of core substrate


80


. A pair of largely identical layers


144


of a liquidous composition of a carbon-containing ceramic precursor and a suitable liquid are formed on the opposite faces of core substrate


80


.

FIG. 14



a


depicts one of precursor-containing liquidous layers


144


.




As described further below, each molecule of the carbon-containing ceramic precursor material in liquidous layers


144


contains multiple carbon-containing groups, one or more of which are readily retainable during cross-linking of the precursor material and one or more of which are readily releasable during the precursor cross-linking. The molecules of the ceramic precursor material thus provide both a cross-linking capability and serve as a source of carbon when the cross-linking is complete.




Subject to providing the foregoing dual-function capability, the ceramic precursor material is normally an organically modified precursor in which the retainable and releasable carbon-containing groups are organic groups. The cross-linking of the organically modified ceramic precursor is typically a polymerization reaction. The organically modified precursor may contain metalorganic material in which there are metal-oxygen-carbon bonds or/and organometallic material in which there are direct metal-carbon bonds.




The metallic cations in the precursor material consist of one or more non-carbon elements in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a in Periods 2-6 of the Periodic Table, including the lanthanides. As with thin films


92


, particularly attractive ceramic cation candidates for the precursor material in layers


144


are silicon, titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten. Two or more of these metallic cation candidates may be present in the precursor material, typically in mixed form.




More particularly, the ceramic precursor material can be constituted as described above for the ceramic precursor used in forming thin films


92


as gels in the process of FIG.


6


. Candidates for the ceramic precursor material in liquidous layers


144


include metallic alkoxides having both retainable and releasable carbon-containing groups or/and other compounds having both retainable and releasable carbon-containing groups. In a typical implementation, the metallic cations are silicon. The precursor material consists of alkylalkoxysilane having both retainable and releasable organic groups.




The liquid in precursor-containing liquidous layer


144


is normally an organic solvent. Examples of the organic solvent include alcohols such as ethanol and isopropanol, ketones such as acetone and methylisobutylketone, and polyols such as ethylene glycol. The solvent may also contain other organic room-temperature liquids in which the precursor material is miscible. When the precursor material is alkylalkoxysilane, the liquid is typically an alcohol such as ethanol.




Each precursor-containing liquidous layer


144


is normally formed to a thickness of 10 nm-10 μm on core substrate


80


. Any of the above-described dipping, spraying, deposition/spinning, and vapor-condensation techniques utilized to create thin films


92


can be employed to form liquidous layers


144


. Likewise, the formation of layers


144


can be performed in a homogeneous or heterogeneous manner. Each layer


144


may be formed in one or more coating steps.




Precursor-containing liquidous layers


144


are processed in substantially the same way in later operations. Only one of layers


144


is, for simplicity, dealt with in the remainder of the process description for FIG.


14


.




Molecules of the organic precursor material in illustrated precursor-containing liquidous layer


144


cross-link to form a layer-like initial porous body


146


as shown in

FIG. 14



b


. Various mechanisms such as use of a catalyst, changes in pH, changes in ionic strength, or/and heating can be employed to promote the cross-linking. The liquid in liquidous layer


144


is also removed. The liquid removal can be performed by drying layer


144


at approximately room temperature. Alternatively or additionally, heat can be employed to remove the liquid provided that the heat does not cause undesired chemical reactions to occur. Part of the liquid is typically a byproduct of the cross-linking action.




The cross-linking and liquid removal can be performed according to a sol-gel process of the type described above in connection with the process of FIG.


6


. In being converted to initial porous layer


146


, precursor-containing liquidous layer


144


then goes through a gel stage. Liquid is removed from the film-like gel without causing the cross-linked precursor material to fully collapse and fill the space previously occupied by the liquid. As a result, porous layer


146


contains randomly distributed irregular initial pores


148


. The average diameter of initial pores


148


is normally 1-1,000 nm, preferably 1-200 nm.




During the precursor-material cross-linking, some of the carbon-containing, normally organic, groups of the precursor molecules undergo chemical reactions and are released from the cross-linked material. The released carbon-containing groups dissolve in the liquid or/and become part of the liquid. Importantly, some of the carbon-containing groups of the precursor molecules are retained in the cross-linked material. The ends of the retained carbon-containing groups generally tend to move into the liquid. Consequently, retained carbon-containing groups extend along the surfaces of initial pores


148


when the cross-linking and liquid removal are complete. In particular, the surfaces of pores


148


are largely formed by retained carbon-containing groups of the precursor molecules.




Initial porous layer


146


is now treated to remove non-carbon constituents of at least the retained carbon-containing groups along initial pores


148


.

FIG. 14



c


depicts the resultant structure in which porous layer


146


has been converted into porous layer


82


and overlying multi-part carbon-containing coating


140


. Pores


148


have been respectively converted into further pores


58


. Due to the removal of the non-carbon constituents along pores


148


, further pores


58


are somewhat larger than initial pores


148


. The portion of carbon-containing coating


140


along rough face


54


forms conformal coating


88


. During the treatment to remove non-carbon constituents of retained carbon-containing groups, some cross-linking occurs to form bonds among the remaining carbon atoms.




The treatment to remove the non-carbon material along initial pores


148


can be performed in various ways. For example, initial porous layer


146


can be heated to pyrolize the retained carbon-containing, normally organic, groups. The pyrolysis is normally performed in a vacuum or other non-reactive environment such as nitrogen or/and inert gas. The pyrolysis temperature is normally 200-900° C., typically 250-500° C. Alternatively or additionally, layer


146


can be subjected to a plasma, an electron beam, ultraviolet light, or/and a reducing atmosphere, such as a mixture of hydrogen and nitrogen, to remove the non-carbon material along pores


148


.




In the structure of

FIG. 14



c


, porous layer


82


normally consists principally of oxide of one or more of the metals and metal-like elements used in precursor-containing liquidous layer


144


. Related metallic hydroxide may also be present in layer


82


.




Because the minimum diameter of pores


148


was 1 nm, the minimum diameter of pores


58


is approximately 5 nm here.





FIGS. 15



a


-


15




c


(collectively “FIG.


15


”) depict another process for manufacturing a structure such as main wall


46


in which conformal coating


88


consists principally of carbon. The process of

FIG. 15

begins with a substructure consisting of core substrate


80


. A pair of largely identical primary solid layer-like porous bodies


150


are formed along the opposite faces of core substrate


80


.

FIG. 15



a


depicts one of primary porous layers


150


.




Primary porous layers


150


are created in the same way as porous layers


82


in the process of FIG.


6


. Irregular primary pores


152


are randomly distributed throughout each porous layer


150


. The average diameter of primary pores


152


is normally 5-1,000 nm. The combination of core substrate


80


and porous layers


150


forms a primary structural body in which layers


150


have the porosity characteristics prescribed above for main wall


46


. The minimum porosity of each layer


150


is normally at least 10%.




Each solid porous layer


150


normally consists principally of oxide or/and hydroxide of one or more non-carbon elements in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, again including the lanthanides. As in the process of

FIG. 6

, particularly attractive candidates for the metallic cations of the material in layers


150


are silicon, titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten. Two or more of these cation candidates may be present in each layer


150


, typically in mixed form. A hydroxyl layer typically extends along primary pores


152


to form their surfaces.




In subsequent steps, porous layers


150


are processed in substantially the same way. For simplicity, only one of layers


150


is dealt with in the remainder of the process description for FIG.


15


. Illustrated porous layer


150


has a rough face


154


. Carbon-containing chain molecules are brought into contact with layer


150


, including the surfaces of primary pores


152


along face


54


. Each carbon-containing chain molecule has one or more carbon-containing chains, normally organic, and one or more leaving species. Each leaving species is normally hydrolyzable, and each carbon-containing chain is normally non-hydrolyzable. The chain molecules have an average chain length of 1-100 nm, preferably 2-20 nm. When a chain molecule has two or more carbon-contaning chains, the chain length of the molecule is the sum of the lengths of the molecule's carbon-containing chains.




The chain molecules chemically bond to porous layer


150


, including the surfaces of primary pores


150


along rough face


54


, by reactions that largely only involve the leaving species to produce a very thin carbon-containing film


156


along face


54


. See

FIG. 15



b


. Layer


150


is thereby converted into porous layer


82


as primary pores


152


are respectively converted into irregular intermediate pores


158


. Due to the presence of carbon-containing film


156


, intermediate pores


158


are slightly smaller than primary pores


152


. Since the retained carbon-containing groups are normally organic groups, carbon-containing film


156


is normally an organic film.




The chemical bonding of the carbon-containing chain molecules to porous layer


150


normally occurs by hydrolysis of the leaving species. Specifically, the chain molecules normally bond to oxygen atoms of the hydroxyl layer typically provided along rough face


54


as hydrogen atoms and one or more leaving species of each chain molecule are released. The released hydrogen atoms and leaving species at least form water.




Alternatively, rough face


154


may be formed by a layer of oxygen atoms. The thickness of the oxygen layer is normally no more than approximately a monolayer of oxygen atoms. The oxygen layer forms oxide with the underlying metallic atoms of porous layer


150


. To create the oxygen layer, a rough face of a precursor to porous layer


150


is exposed to oxygen. The carbon-containing chain molecules bond directly to the oxygen layer without significant hydrogen release.




Prior to being bonded to primary porous layer


150


, each carbon-containing chain molecule is generally representable as:











where, X is a multivalent coupling atom, Lv is a leaving species, Ch is a carbon-containing, normally organic, chain having at least three carbon atoms, and each of R


1


and R


2


is a further species. Multivalent coupling atom X has a valence of at least two. As discussed below, but not indicated in the preceding chain molecule representation, the valence of coupling atom X can be up to seven.




Each of species R


1


and R


2


is (a) nothing, (b) a leaving species, (c) an alkyl or alkoxy group having up to two carbon atoms, (d) a carbon-containing, normally organic, chain having at least three carbon atoms, or (e) a non-carbon species including a hydrogen or deuterium atom. The word “nothing” as used here in connection with species R


1


or R


2


means that species R


1


or R


2


, while included in the foregoing representation of the chain molecule, is not actually present in the molecule. Inasmuch as species R


1


or R


2


can be a leaving species or a carbon-containing chain, multivalent coupling atom X can be chemically bonded to (a) one leaving species and one carbon-containing chain, (b) one leaving species and two carbon-containing chains, (c) two leaving species and one carbon-containing chain, (d) one leaving species and three carbon-containing chains, (e) two leaving species and two carbon-containing chains, or (f) three leaving species and one carbon-containing chain.




Multivalent coupling atom X is typically tetravalent. In this case, only bonding arrangements (d) one leaving species and three carbon-containing chains, (e) two leaving species and two carbon-containing chains, and (f) three leaving species and one carbon-containing chain apply to coupling atom X. Tetravalent candidates for coupling atom X include silicon, titanium, germanium, zirconium, tin, and lead. Aluminum and iron are trivalent candidates for coupling atom X for which bonding arrangements (b) one leaving species and two carbon-containing chains and (c) two leaving species and one carbon-containing chain are applicable. In the trivalent case, only one of species R


1


and R


2


is present. Neither of species R


1


and R


2


is present when coupling atom X is bivalent. When porous layer


150


consists of metal oxide of the above described type, preferably with a hydroxyl surface layer, coupling atom X is preferably one of silicon, titanium, and iron.




Each leaving species is normally a halogen atom, an alkoxy group, an acetoxy group, an amine group, a hydroxyl group, or a hydrogen or deuterium atom provided that neither of species R


1


and R


2


is a hydrogen or deuterium atom. Candidates for the halogen atom as a leaving species are fluorine, chlorine, bromine, and iodine. In cases where multiple leaving species are bonded to coupling atom X, the leaving species can be the same or different.




Each carbon-containing chain is normally an aliphatic group, an aromatic group, a vinyl group (with a double carbon-carbon bond), a mercapto/thio group (with sulfur bonded to an alkyl group), an amine group (with nitrogen bonded to an alkyl group), a methacryloxypropyl group, or a glycidoxypropyl group. Suitable examples of aliphatic and aromatic groups respectively are alkyl and phenyl groups. In cases where multiple carbon-containing chains are bonded to coupling atom X, the carbon-containing chains can be the same or different.




When species R


1


or R


2


is a non-carbon group, the non-carbon group does, of course, not contribute to the carbon eventually produced in conformal coating


88


. However, implementing species R


1


or R


2


with a non-carbon group in the form of a hydrogen or deuterium atom yields a relatively simple carbon-containing chain molecule. Also, in some situations, it may be desirable for the chain molecules to provide a capability besides a carbon source. This additional capability can be achieved by appropriately choosing a suitable non-carbon group for species R


1


or R


2


.




Although not indicated in the preceding representation of the initial form of each carbon-containing chain molecule, up to three additional species R


n


, where n is a positive integer other than 1 or 2, may be bonded to coupling atom X prior to the step in which the chain molecules bond to porous layer


150


. For instance, there may be (a) one additional species R


3


, atom X then being pentavalent, (b) two additional species R


3


and R


4


, atom X then being hexavalent, or (c) three additional species R


3


, R


4


, and R


5


, atom X then being heptavalent.




Each additional species R


n


is constituted the same as species R


1


or R


2


. Letting each carbon-containing chain molecule be further represented as having up to three additional species R


n


bonded to atom X, each additional species R


n


thus is (a) nothing, (b) a leaving species, (c) an alkyl or alkoxy group having up to two carbon atoms, (d) a carbon-containing, normally organic, chain having at least three carbon atoms, or (e) a non-carbon species including a hydrogen or deuterium atom. Since each additional species R


n


can be a leaving species or a carbon-containing chain, the number of permutations of leaving species and carbon-containing chains is considerably more than that described above in connection with species R


1


and R


2


.




In a typical implementation, each carbon-containing chain molecule is a chlorosilyl species, a dichlorosilyl species, a chloroalkoyysilyl species, or a dichloroalkoyysilyl species as represented below:











where species R is a hydrocarbon group having at least three carbon atoms. The hydrocarbon group may be an alkyl group or an aromatic group. The R or O—R group is an organic chain. Species R


1


or R


2


here is a hydrogen (or deuterium) atom or an alkyl group having up to two carbon atoms. The alkyl group here is typically a methyl group. Each chlorine atom is a leaving species.




In another typical implementation, each organic chain molecule is a chlorotitanyl species, a dichlorotitanyl species, a chloroalkoxyltitanyl species, or a dichloroalkoxytitanyl species. The representations of the chlorotitanyl, dichlorotitanyl, chloroalkoxyltitanyl, and dichloroalkoxytitanyl species are respectively the same as the preceding representations for the chlorosilyl, dichlorosilyl, chloroalkoxysilyl, and dichloroalkoxysilyl species except that a titanium atom replaces each silicon atom. Further candidates for the chain molecules are presented in Arkles, “Silicon, Germanium, Tin, and Lead Compounds, Metal Alkoxides, Diketonates and Carboxylates, A Survey of Properties and Chemistry,” 2d ed., Gelest, Inc., 1998, the contents of which are incorporated by reference herein.




Various techniques can be employed to bring the carbon-containing chain molecules into contact with solid porous layer


150


. A vapor of the chain molecules can be exposed to layer


150


. The chain molecules can be directly sprayed on layer


150


. Any liquid which is produced during the bonding reaction and which is not volatized is removed in the course of the vapor exposure or spraying procedure.




The carbon-containing chain molecules can also be combined with a liquid to form a liquidous composition. Porous layer


150


can then be dipped in the liquidous composition. Alternatively, a portion of the liquidous composition can be sprayed on layer


150


. Yet further, a portion of the liquidous composition can be deposited on layer


150


and, as necessary, spun to achieve a relatively uniform thickness. The liquid in the portion of the liquidous composition along rough face


54


is subsequently removed, typically by drying at approximately room temperature. Alternatively or additionally, heat can be utilized to remove the liquid provided that the heat does not cause any undesired chemical reactions.




Turning to

FIG. 16

, it qualitatively presents an exploded view of a portion of the structure of

FIG. 15



b


. In the qualitative example of

FIG. 16

, each bonded chain molecule in carbon-containing film


156


has three carbon-containing chains. As

FIG. 16

indicates, the bonded chain molecules of film


156


are distributed in a random manner along rough face


54


, including the surface of each intermediate pore


158


.




Carbon-containing film


156


is treated to remove the non-carbon constituents of the bonded carbon-containing chain molecules. The resultant structure is depicted in

FIG. 15



c


where film


156


has been converted into carbon-containing conformal coating


88


. Intermediate pores


158


thereby respectively become further pores


58


. Due to the removal of the non-carbon constituents of the chain molecules, further pores


58


are of greater average diameter than intermediate pores


158


.




The percentage of carbon in conformal coating


88


here is normally more than 50%, typically at least 80%. The carbon in coating


88


normally is largely all amorphous carbon. During the treatment of film


56


to remove non-carbon constituents of the bonded chain molecules, cross-linking occurs to create carbon-carbon bonds.




The thickness of conformal coating


88


in

FIG. 15



c


is normally 1-100 nm, preferably 5-50 nm. As with carbon-containing coating


140


/


88


in

FIG. 13

, the thickness of coating


88


in

FIG. 15



c


is normally highly uniform. The standard deviation in the thickness of layer


88


in

FIG. 15



c


is preferably no more than 20%, more preferably no more than 10%, of the average coating thickness. This thickness uniformity in coating


88


of

FIG. 15



c


enables coating


88


to be made quite thin so as to reduce the power dissipation in main wall


46


without significantly exposing underlying porous layer


82


and thereby increasing the secondary electron emission.




The removal of the non-carbon constituents in organic film


156


can be performed in a variety of ways. Film


156


can be heated to pyrolize the bonded organic chain molecules. The pyrolysis is usually done in a vacuum or other non-reactive environment such as nitrogen or/and inert gas. As in the process of

FIG. 14

, the pyrolysis temperature is normally 200-900° C., typically 250-500° C. Alternatively or additionally, film


156


can be subjected to a plasma, an electron beam, ultraviolet light, or/and a reducing environment to remove the non-carbon constituents of the bonded chain molecules.




In the exemplary process of

FIG. 15

, carbon-containing film


156


is converted into conformal coating


88


that adjoins porous layer


82


. Alternatively, carbon-containing chain molecules may be brought into contact with a separate conformal coating that lies on layer


82


. The chain molecules then bond to this conformal coating, rather than to earlier porous layer


150


, to form a thin carbon-containing film along the conformal coating. The carbon-containing film is then converted largely to carbon in the manner described above for converting film


156


into carbon. If the conformal coating that adjoins layer


82


is of lower average total natural electron yield coefficient a than layer


82


, the conformal coating and the overlying carbon-containing film cooperate with each other to form conformal coating


88


as a multi-layer coating. Alternatively, the conformal coating that adjoins layer


82


can provide a capability other than reducing the total natural electron yield.




If the conformal coating that adjoins


82


in this variation does not have a surface hydroxyl layer, the fabrication of a carbon-containing coating on the lower conformal coating typically entails exposing the lower conformal coating to oxygen to form a surface oxygen layer of no more than approximately a monolayer in thickness. The carbon-containing chain molecules then bond to the oxygen layer in the manner described above for creating organic film


156


. Consequently, the carbon-containing film produced from the bonded chain molecules can be processed in the way described above for film


156


.




Taking note of the fact that item


80


in the process of each of

FIGS. 14 and 15

represents either core substrate


80


or the larger precursor substrate from which multiple substrates


80


can be made, the structure in each of

FIGS. 14



c


and


15




c


implements main wall


46


when item


80


represents core substrate


80


. When item


80


represents the larger precursor substrate, the structure in each of

FIGS. 14



c


and


15




c


can be cut into multiple portions to form multiple walls


46


. The formation of electrodes


48


,


50


, and


52


is integrated with the process of each of

FIGS. 14 and 15

in the manner prescribed above.




The structure of each of

FIGS. 14



c


and


15




c


, although particularly suitable for partial or full use in spacer wall


24


, can be employed in other applications. For instance, the structure of

FIG. 14



c


or


15




c


can be utilized as a catalyst or in a chemical gas sensor of high surface area.




Main Spacer Wall Having Layer With Directional Resistivity Characteristic





FIG. 17

depicts a further embodiment of a portion of main spacer wall


46


along rough face


54


, and an adjoining portion of faceplate structure


22


. Core substrate


80


of wall


46


here is a support body having a face


160


which is typically relatively smooth but may have some roughness and on which porous layer


82


is situated. In the embodiment of

FIG. 17

, layer


82


is a substantially unitary primary layer having a directional resistivity characteristic in which the layer's average resistivity parallel to support-body face


160


is greater than the layer's average resistivity perpendicular to face


160


. As used here, the term “unitary” means that layer


82


, while being porous, is substantially a single piece of material. That is, each part of layer


82


is connected to each other part of layer


82


through material of layer


82


.




In order to better understand the directional resistivity characteristic,

FIG. 17

is illustrated with respect to a standard xyz coordinate system in combination with an rθz polar coordinate system. The xy plane in the xyz coordinate system extends parallel to an imaginary plane passing generally through support-body face


160


. The z coordinate thus extends perpendicular to the plane running through face


160


. Radial coordinate r lies in the xy plane. Angular coordinate θ is measured counter-clockwise in the xy plane starting from the x axis.




Porous layer


82


has an average scalar electrical resistivity ρ





parallel to support-body face


160


and thus parallel to the xy and rθ planes. In any direction in the rθ plane, the average vector electrical resistivity {overscore (ρ)}





of layer


82


approximately equals ρ





î


r


, where î


r


is a unit vector along radial coordinate r. Layer


82


has an average scalar electrical resistivity ρ





perpendicular to face


160


and thus along the z axis. The average vector electrical resistivity {overscore (ρ)}





of layer


82


in the z direction equals ρ





î


z


, where î


z


is a unit vector in the z direction.




With the foregoing in mind, average scalar resistivity ρ





is greater than average scalar resistivity ρ





. Resistivity ρ





is normally at least twice, preferably at least ten times, resistivity ρ





. Typically, resistivity ρ





is at least one hundred times resistivity ρ





. Also, porous layer


82


in

FIG. 17

has a sheet resistance of at least 10


13


ohms/sq., preferably at least 10


14


ohms/sq., parallel to support-body face


160


. Layer


82


has the porosity characteristics described above. That is, the minimum porosity of layer


82


, at least along rough face


54


, is 10%.





FIG. 18

depicts an implementation of the display portion in FIG.


17


. In

FIG. 18

, porous layer


82


consists of an electrically non-conductive base layer


162


and a plurality of electrically non-insulating resistivity-modifying regions


164


. Base layer


162


is situated directly on core substrate


80


, i.e., the support body. The resistivity-modifying regions


164


occupy laterally separated sites laterally surrounded by base layer


162


. Each resistivity-modifying region


164


contacts substrate


80


and extends substantially through base layer


162


. Consequently, no more than approximately a monolayer of regions


164


are normally present in layer


82


.




The electrical resistivity of base layer


162


is relatively uniform throughout layer


162


. The electrical resistivities of resistivity-modifying regions


164


are relatively uniform from one region


164


to another. Importantly, the average resistivity of regions


164


is less than the average resistivity of base layer


162


. As a result, average scalar resistivity ρ





exceeds average scalar resistivity ρ





.




The implementation of

FIG. 18

typically includes conformal coating


88


on top of base layer


162


and resistivity-modifying regions


164


. When coating


88


is present, the structure of

FIG. 18

implements main wall


46


of

FIG. 5



c


. Coating


88


in

FIG. 18

is normally electrically non-insulating. If coating


88


is absent, the structure of

FIG. 18

implements wall


46


of

FIG. 5



a


. Regardless of whether coating


88


is present or absent, regions


164


provide electrical paths substantially through layer


164


perpendicular to substrate face


160


.




When high-energy primary electrons strike main wall


46


and cause secondary electron emission, the relative low value of average scalar resistivity ρ





enables the charge that accumulates on the outside of wall


46


due to primary electrons striking wall


46


to be rapidly transferred through porous layer


82


to core substrate


80


and then removed. Although electrons are negatively charged, the charge that accumulates on the outside of wall


46


is normally positive because total roughness-modified electron yield coefficient σ* of the material along rough face


54


is usually greater than 1, i.e., the number of secondary electrons that escape a unit projected area of wall


46


is greater than the number of primary electrons that strike a unit projected wall area and accumulate on the outside of wall


46


. The positive charge moves rapidly through porous layer


82


along the electrical paths formed by resistivity-modifying regions


164


.




During FED operation, the anode in faceplate structure


22


is maintained at a potential much higher than the potentials of the electron-emissive elements in backplate structure


20


. In particular, the anode potential is typically 4,000-10,000 volts higher than the potentials of the electron-emissive elements. The relatively high value of average scalar resistivity ρ





serves to limit the current that flows through porous layer


82


from faceplate structure


22


to backplate structure


20


(or vice versa) due to the high potential difference between plate structures


22


and


20


. By reducing the (leakage) current that flows through layer


82


from faceplate structure


22


to backplate structure


20


, the FED's power dissipation is reduced, thereby improving the operational efficiency. Damage that might possibly occur to layer


82


due to excessive current that flows from faceplate structure


22


through layer


82


to backplate structure


20


is also avoided.




Additionally, a large majority of the current flowing from faceplate structure


22


through spacer wall


24


to backplate structure


20


flows through core substrate


80


. Consequently, substrate


80


substantially provides a current path between plate structures


22


and while porous layers


82


and


84


serve to avoid charge buildup on spacer wall


24


. This separation of functions facilitates spacer design.




The electrically non-conductive material of base layer


162


is preferably electrically resistive. Subject to this limitation, layer


162


is normally formed with any of the materials described above for porous layer


82


in the process of FIG.


6


. These materials include oxides and hydroxides of one or more non-carbon elements in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table, including the lanthanides. For layer


162


, particularly attractive oxides and hydroxides are those of silicon, titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten, including oxides and hydroxides of two or more of these elements typically in mixed form.




Resistivity-modifying regions


164


are typically roughly spherical but can have other shapes. The average diameter of regions


164


is normally 5-500 nm, typically 50-200 nm. On the average, regions


164


typically protrude 5-50% (of the way) out of base layer


162


.




Resistivity-modifying regions


164


preferably are electrically conductive. In a typical implementation, regions


164


consist principally of electrically conductive carbon. The percentage of carbon in regions


164


is normally more than 50%, preferably at least 80%. The carbon in regions


164


is normally in the form of one or more of amorphous carbon, graphite, and diamond or diamond-like carbon.




Conformal coating


88


in

FIG. 18

is also preferably electrically conductive. In a typical implementation, coating


88


here consists principally of electrically conductive carbon. The percentage of carbon in coating


88


is normally more than 50%, preferably at least 80%. The carbon in coating


88


is normally substantially all amorphous carbon or/and diamond-like carbon.





FIGS. 19



a


-


19




c


(collectively “FIG.


19


”) illustrate a process for manufacturing a structure such as main wall


46


in which porous layer


82


is formed with base layer


162


and resistivity-modifying regions


164


to provide a directional resistivity characteristic of the type described above in connection with

FIGS. 17 and 18

. The process of

FIG. 19

begins with core substrate


80


. A pair of largely identical thin liquid-containing layer-like bodies


166


are formed on the opposite faces of core substrate


80


.

FIG. 19



a


depicts one of liquidous layers


166


.




Each liquid-containing layer


166


consists of resistivity-modifying regions


164


, a ceramic precursor to base layer


162


, and a suitable liquid. Subject to producing layer


162


so as normally to be electrically resistive, the ceramic precursor can be any of the ceramic precursor materials described above for thin films


92


in the process of FIG.


6


. Hence, the ceramic precursor in liquid-containing layers


166


is typically metallic alkoxide but could alternatively or additionally include other metalorganic or organometallic materials. The liquid is normally an organic solvent of the type described above for films


92


.




Liquid-containing layers


166


are formed on core substrate


80


according to any of the techniques described above for creating thin films


92


on substrate


80


, subject to one principal limitation. Each layer


166


is normally of a thickness corresponding to no more than approximately a monolayer of resistivity-modifying regions


164


depending on the density of regions


164


in layers


166


. Excluding resistivity-modifying regions


164


, the minimum thickness of each layer


166


is normally in the vicinity of the average diameter of regions


164


.




In subsequent operations, liquid-containing layers


166


are processed substantially the same. Only one of layers


166


is, for simplicity, dealt with in the remainder of the process description for FIG.


19


.




The ceramic precursor material in illustrated liquid-containing layer


166


is converted into base layer


162


as depicted in

FIG. 19



b


. The liquid in liquid-containing layer


166


is also removed.




The precursor conversion and liquid removal can be performed according to a sol-gel process as described above in connection with the process of FIG.


6


. Although not indicated in

FIG. 19

, liquid-containing layer


166


then goes through a gel stage in which an initial polymeric gel layer laterally surrounds resistivity-modifying regions


164


. The liquid is removed without causing the gel to fully collapse. Irregular pores


168


are thereby produced at random locations throughout base layer


162


. Regions


164


protrude out of layer


162


.




Alternatively, porous layer


82


can be created from resistivity-modifying regions


164


and ceramic precursor particles. In this case, liquid-containing layer


166


consists of a liquid-containing composition of regions


164


, ceramic precursor particles, and a suitable liquid, typically water. The ceramic precursor particles typically have the characteristics described above for the ceramic precursor particles in thin films


92


in the process of FIG.


6


. Likewise, layer


166


is processed in substantially the same way that each layer


92


is processed when it consists of ceramic precursor particles and liquid. As a further alternative, layer


82


can be created from resistivity-modifying regions


164


and a combination of polymeric ceramic precursor material and ceramic precursor particles.




Conformal coating


88


consisting of carbon is formed along the exposed face of porous layer


82


, including the surfaces of pores


168


situated along the exposed face of layer


82


. See

FIG. 19



c


. Various techniques can be utilized to form conformal carbon-containing coating


88


here. For example, coating


88


can be formed according to the process of FIG.


15


. Alternatively, coating


88


can be formed according to the process of FIG.


14


. In this event, the carbon-containing material also defines the surfaces of externally inaccessible pores


58


.




As indicated above, item


80


in the process of

FIG. 19

represents either core substrate


80


or a larger precursor substrate from which two or more substrates


80


can be made. The structure in

FIG. 19



c


then either represents main wall


46


or can be cut into multiple portions to form multiple walls


46


. In either case, the formation of electrodes


48


,


50


, and


52


is integrated with the process of

FIG. 19

in the way prescribed above.




The structure of

FIG. 19



c


, although being particularly suitable for partial or full use in spacer wall


24


, can be employed in other applications. As an example, the structure of

FIG. 19



c


can be used in particle detectors such as electron detectors.




Additional Variations




Directional terms such as “lateral”, “above”, and “below” have been employed in describing the present invention to establish a frame of reference by which the reader can more easily understand how the various parts of the invention fit together. In actual practice, the components of a flat-panel CRT display may be situated at orientations different from that implied by the directional terms used here. Inasmuch as directional terms are used for convenience to facilitate the description, the invention encompasses implementations in which the orientations differ from those strictly covered by the directional terms employed here.




While the invention has been described with reference to particular embodiments, this description is solely for the purpose of illustration and is not to be construed as limiting the scope of the invention claimed below. For instance, the spacers in the spacer system can be formed as posts or as combinations of walls. The cross-section of a spacer post, as viewed along the length of the post, can be shaped in various ways such a circle, an oval, or a rectangle. As viewed along the length of a spacer consisting of a combination of walls, the spacer can be shaped as a “T”, an “H”, or a cross.




The sheet resistance R





of a spacer of arbitrary shape is approximately:










R


=


RP
DAV


2

L






(
1
)













where R is the spacer's resistance between plate structures


20


and


22


, P


DAV


is the average dimension of the perimeter of the spacer as viewed in the forward (or reverse) electron-travel direction, and L is the length of the spacer in the forward (or reverse) electron-travel direction. Ignoring the thickness of a wall-shaped spacer (including a spacer shaped like a curved wall), perimeter P


DAV


of a wall-shaped spacer is twice its average width W


AV


as viewed in the forward electron-travel direction. For a wall-shaped spacer, Eq. 1 simplifies to:










R


=


RW
AV

L





(
2
)













By using Eqs. 1 and 2, the sheet resistance information specified above for main wall


46


in wall-shaped spacer


24


can be correlated to that appropriate to a spacer shaped as a post, as a combination of walls, or in another configuration besides a single wall.




Field emission includes the phenomenon generally termed surface conduction emission. Backplate structure


20


that operates in field-emission mode can be replaced with an electron emitter that operates according to thermionic emission or photoemission. Rather than using control electrodes to selectively extract electrons from the electron-emissive elements, the electron emitter can be provided with electrodes that selectively,collect electrons from electron-emissive elements which continuously emit electrons during display operation. Various modifications and applications may thus be made by those skilled in the art without departing from the true scope and spirit of the invention as defined in the appended claims.



Claims
  • 1. A flat-panel display comprising:a first plate structure for emitting electrons; a second plate structure, situated opposite the first plate structure, for producing an image upon receiving electrons emitted by the first plate structure; and a spacer situated between the plate structures, the spacer comprising a substrate and an overlying porous body in which particle aggregates are bonded together in an open manner such that pores extend between the aggregates, each aggregate comprising multiple particles bonded together, each of at least part of the particles, including at least part of those particles internal to the aggregates, being a coated particle comprising a support particle and a differently constituted particle coating that adjoiningly covers most of the support particle.
  • 2. A display as in claim 1 wherein the pores inhibit secondary electrons emitted by the spacer from escaping the spacer.
  • 3. A display as in claim 1 wherein the porous body has a porosity of at least 10% along a face thereof spaced apart from the substrate and extending at least partway from either plate structure to the other plate structure.
  • 4. A display as in claim 3 wherein the pores are present along largely all of the porous body's face.
  • 5. A display as in claim 1 wherein the particle coating of each coated particle adjoiningly covers largely all of its support particle.
  • 6. A display as in claim 1 wherein the particle coatings are of lower average total natural electron yield coefficient than the support particles.
  • 7. A display as in claim 1 wherein the support particles comprise at least one of: (a) oxide of at least one non-carbon element in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table including the lanthanides; and (b) hydroxide of at least one non-carbon element in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a and 4a of Periods 2-6 of the Periodic Table including the lanthanides.
  • 8. A display as in claim 1 wherein the particle coatings comprise at least one of: (a) oxide of at least one of titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten; and (b) hydroxide of at least one of titanium, vanadium, chromium, manganese, iron, germanium, yttrium, zirconium, niobium, molybdenum, tin, cerium, praseodymium, neodymium, europium, and tungsten.
  • 9. A display as in claim 1 wherein:the support particles comprise at least one of (a) oxide of at least one of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium and (b) hydroxide of at least one of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium; and the particle coatings comprise at least one of (a) oxide of at least one of titanium, chromium, manganese, iron, zirconium, cerium, and neodymium and (b) hydroxide of at least one of titanium, chromium,.manganese, iron, zirconium, cerium, and neodymium.
  • 10. A display as in claim 9 wherein the particle coatings are of different chemical composition than the support particles.
  • 11. A display as in claim 1 wherein the porous body has an average electrical resistivity of 108-1014 ohm-cm.
  • 12. A display as in claim 1 wherein the substrate is shaped generally like a wall.
  • 13. A flat-panel display comprising:a first plate structure for emitting electrons; a second plate structure, situated opposite the first plate structure, for producing an image upon receiving electrons emitted by the first plate structure; and a spacer situated between the plate structures, the spacer comprising (a) a porous body having a face that extends at least partway from either plate structure to the other plate structure and (b) a coating that overlies the porous body's face and consists principally of carbon, multiple primary pores extending into the porous body along its face, the coating also extending along the primary pores to coat their surfaces and to convert the primary pores into further pores, the thickness of the coating having a standard deviation of no more than 20% of the average thickness of the coating.
  • 14. A display as in claim 13 wherein the standard deviation in the thickness of the coating is no more than 10% of the average thickness of the coating.
  • 15. A display as in claim 13 wherein:the further pores inhibit secondary electrons emitted by the spacer from escaping the spacer; and the coating further inhibits secondary electrons emitted by the spacer from escaping the spacer.
  • 16. A display as in claim 13 wherein the average thickness of the coating is 1-100 nm.
  • 17. A display as in claim 16 wherein the primary pores have an average diameter of 1-1,000 nm.
  • 18. A display as in claim 13 wherein the spacer has a porosity of at least 10% along the coating.
  • 19. A display as in claim 13 wherein the pores are present along largely all of the porous body's face.
  • 20. A display as in claim 13 wherein the porosity of the spacer is at least 20% along the coating.
  • 21. A display as in claim 13 wherein the porous body comprises at least one of oxide and hydroxide.
  • 22. A display as in claim 13 wherein the spacer further includes an electrically non-conductive substrate over which the porous body is situated such that the porous body's face is spaced apart from the substrate.
  • 23. A display as in claim 13 wherein the spacer is shaped generally like a wall.
  • 24. A flat-panel display comprising:a first plate structure for emitting electrons; a second plate structure, situated opposite the first plate structure, for producing an image upon receiving electrons emitted by the first plate structure; and a spacer situated between the plate structures, the spacer comprising (a) a porous body having a face that extends at least partway from either plate structure to the other plate structure and (b) a multi-part coating that overlies the porous body's face and consists principally of carbon, the porous body having multiple primary pores, part of which are substantially fully enclosed by the porous body so as to be directly externally inaccessible, the coating extending along the primary pores to coat their surfaces and convert the primary pores, including those that are directly externally inaccessible, into further pores.
  • 25. A display as in claim 24 wherein:directly externally accessible ones of the further pores inhibit secondary electrons emitted by the spacer from escaping the spacer; and material of the coating along the directly externally accessible ones of the further pores further inhibits secondary electrons emitted by the spacer from escaping the spacer.
  • 26. A structure as in claim 24 wherein the average thickness of the coating is 1-100 nm.
  • 27. A structure as in claim 26 wherein the primary pores have an average diameter of 5-1,000 nm.
  • 28. A structure as in claim 24 wherein the structure has a porosity of at least 10% along the coating.
  • 29. A display as in claim 24 wherein the spacer is shaped generally like a wall.
  • 30. A flat-panel display comprising:a first plate structure for emitting electrons; a second plate structure, situated opposite the first plate structure, for producing an image upon receiving electrons emitted by the first plate structure; and a spacer situated between the plate structures, the spacer comprising (a) a spacer support body having a face and (b) a substantially unitary primary layer overlying the support body's face and constituted with primary material having a higher average electrical resistivity parallel to the support body's face than perpendicular to the support body's face.
  • 31. A display as in claim 30 wherein the average electrical resistivity of the primary material parallel to the support body's face is at least twice the average electrical resistivity of the primary material perpendicular to the support body's face.
  • 32. A display as in claim 31 wherein the average electrical resistivity of the primary material parallel to the support body's face is at least ten times the average electrical resistivity of the primary material perpendicular to the support body's face.
  • 33. A display as in claim 31 wherein the primary material has an average sheet resistance of at least 1013 ohms/sq. parallel to the support body's face.
  • 34. A display as in claim 30 wherein the primary layer has a porosity of at least 10%.
  • 35. A display as in claim 34 wherein the porosity of the primary layer is at least 20%.
  • 36. A display as in claim 30 wherein the primary layer comprises:a base layer overlying the support body's face; and a plurality of resistivity-modifying regions that occupy laterally separated sites surrounded by the base layer, the resistivity-modifying regions being of lower average electrical resistivity than the base layer.
  • 37. A display as in claim 36 wherein:the base layer is electrically non-conductive; and the resistivity-modifying regions are electrically non-insulating.
  • 38. A display as in claim 37 wherein multiple ones of the resistivity-modifying regions provide electrical paths substantially through the base layer generally perpendicular to the support body's face.
  • 39. A display as in claim 37 wherein:the base layer comprises electrically resistive material; and the resistivity-modifying regions comprise electrically conductive material.
  • 40. A display as in claim 37 wherein:the base layer comprises at least one of (a) oxide of at least one non-carbon element in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table including the lanthanides and (b) hydroxide of at least one non-carbon element in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table including the lanthanides; the resistivity-modifying regions comprise carbon.
  • 41. A display as in claim 37 wherein the spacer further includes an electrically non-insulating coating overlying the primary layer.
  • 42. A display as in claim 41 wherein:the base layer comprises electrically resistive material; the resistivity-modifying regions comprise electrically conductive material; and the non-insulating coating comprises electrically conductive material.
  • 43. A display as in claim 41 wherein:the base layer comprises at least one of (a) oxide of at least one non-carbon element in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table including the lanthanides and (b) hydroxide of at least one non-carbon element in Groups 3b, 4b, 5b, 6b, 7b, 8, 1b, 2b, 3a, and 4a of Periods 2-6 of the Periodic Table including the lanthanides; the resistivity-modifying regions comprise carbon; and the non-insulating coating comprises carbon.
  • 44. A display as in claim 37 wherein the support body is shaped generally like a wall.
  • 45. A display as in claim 3 wherein the porosity along the porous body's face is at least 20%.
  • 46. A display as in claim 3 wherein the porosity along the porous body's face is at least 40%.
  • 47. A display as in claim 8 wherein the particle coatings are of different chemical composition than the support particles.
  • 48. A display as in claim 1 wherein the particle coatings comprise carbon.
  • 49. A display as in claim 1 wherein:the support particles comprise at least one of (a) oxide of at least one of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium and (b) hydroxide of at least one of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium; and the particle coatings comprise carbon.
  • 50. A display as in claim 1 wherein the particle coatings are of different chemical composition than the support particles.
  • 51. A flat-panel display comprising:a first plate structure for emitting electrons; a second plate structure, situated opposite the first plate structure, for producing an image upon receiving electrons emitted by the first plate structure; and a spacer situated between the plate structures, the spacer comprising a substrate and an overlying porous body in which particle aggregates are bonded together in an open manner such that pores extend between the aggregates, each aggregate comprising multiple particles bonded together, each of at least part of the particles being a coated particle comprising a support particle and a differently constituted particle coating that adjoiningly covers largely all of the support particle.
  • 52. A display as in claim 51 wherein the porous body has a porosity of at least 10% along a face thereof spaced apart from the substrate and extending at least partway from either plate structure to the other plate structure.
  • 53. A display as in claim 51 wherein the particle coatings are of lower average total natural electron yield coefficient than the support particles.
  • 54. A display as in claim 51 wherein:the support particles comprise at least one of (a) oxide of at least one of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium and (b) hydroxide of at least one of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium; and the particle coatings comprise at least one of (a) oxide of at least one of titanium, chromium, manganese, iron, zirconium, cerium, and neodymium, and (b) hydroxide of at least one of titanium, chromium, manganese, iron, zirconium, cerium, and neodymium.
  • 55. A display as in claim 54 wherein the particle coatings are of different chemical composition than the support particles.
  • 56. A display as in claim 51 wherein:the support particles comprise at least one of (a) oxide of at least one of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium and (b) hydroxide of at least one of aluminum, silicon, titanium, chromium, iron, zirconium, cerium, and neodymium; and the particle coatings comprise carbon.
  • 57. A display as in claim 51 wherein the substrate is shaped generally like a wall.
  • 58. A display as in claim 34 wherein the porosity of the primary layer is at least 40%.
CROSS-REFERENCE TO RELATED APPLICATION

This is a division of U.S. patent application Ser. No. 09/209,863, filed Dec. 11, 1998.

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