Fabrication of flat-panel display having spacer with laterally segmented face electrode

FIELD OF USE

This invention relates to flat-panel displays and, in particular, to the configuration of a spacer system utilized in a flat-panel display, especially one of the cathode-ray tube (“CRT”) type.

BACKGROUND ART

A flat-panel CRT display is a thin, flat display which presents an image on the display's viewing surface in response to electrons striking light-emissive material. The electrons can be generated by mechanisms such as field emission and thermionic emission. A flat-panel CRT display typically contains a faceplate (or frontplate) structure and a backplate (or baseplate) structure connected together through an annular outer wall. The resulting enclosure is held at a high vacuum. To prevent external forces such as air pressure from collapsing the display, one or more spacers are typically located between the plate structures inside the outer wall.

FIGS. 1 and 2

, taken perpendicular to each other, schematically illustrate part of a conventional flat-panel CRT display such as that disclosed in Schmid et al, U.S. Pat. No. 5,675,212. The components of this conventional display include backplate structure

20

, faceplate structure

22

, and a group of spacers

24

situated between plate structures

20

and

22

for resisting external forces exerted on the display. Backplate structure

20

contains regions

26

that selectively emit electrons. Faceplate structure

22

contains elements

28

that emit light upon being struck by electrons emitted from electron-emissive regions

26

. Each light-emissive element

28

is situated opposite a corresponding one of electron-emissive regions

26

.

Each of spacers

24

, one of which is fully labeled in

FIGS. 1 and 2

, consists of main spacer wall

30

, end electrodes

32

and

34

, a pair of face electrodes

36

, and another pair of face electrodes

38

. End electrodes

32

and

34

are situated on opposite ends of spacer wall

30

so as to contact plate structures

20

and

22

. Face electrodes

36

form a continuous U-shaped electrode with end electrode

32

. Face electrodes

38

form a continuous U-shaped electrode with end electrode

34

.

It is desirable that spacers in a flat-panel CRT display not produce electrical effects which cause electrons to strike the display's faceplate structure at locations significantly different from where the electrons would strike the faceplate structure in the absence of the spacers. The net amount that the spacers cause electrons to be deflected sideways should be close to zero. Achieving this goal is especially challenging when, as occurs in the conventional display of

FIGS. 1 and 2

, the spacing between consecutive wall-shaped spacers is more than two electron-emissive regions. If spacers

24

cause net electron deflections, the net deflections of electrons emitted from regions

26

located different distances away from the nearest spacer

24

are typically different. This can lead to image degradation such as undesired features appearing on the display's viewing surface.

Face electrodes

36

and

38

are utilized to control the electric potential field along spacers

24

in order to reduce their net effect on the trajectories of electrons moving from regions

26

to elements

28

. However, as discussed in Schmid et al, spacers

24

are typically made by a process in which large sheets of wall material having double-width strips of electrodes

36

and

38

formed on the sheets are mechanically cut along the centerlines of electrodes

36

and

38

. Due to mechanical limitations in performing the cutting operation, the width of each face electrode

36

or

38

can vary along its length.

In turn, the variation in face-electrode width causes the electrical effect that spacers

24

have on the electron trajectories to vary along the spacer length. The net electron deflection resulting from spacers

24

thus varies along their length. Even if the net electron deflection is largely zero at one location along the spacer's length, the net electron deflection at other locations along the spacer's length can cause substantial image degradation. It is desirable to avoid image degradation that arises from width variations of face electrodes that contact end electrodes.

GENERAL DISCLOSURE OF THE INVENTION

In accordance with the invention, a segmented face electrode overlies a face of a main portion of a spacer situated between a pair of plate structures of a flat-panel display. The segmented face electrode is spaced apart from both plate structures, one of which provides the display's image, and also from any spacer end electrodes contacting the plate structures. The face electrode is segmented laterally. That is, the face electrode is divided into a plurality of electrode segments spaced apart from one another as viewed generally perpendicular to either plate structure.

The flat-panel display is normally a flat-panel CRT display in which the image-producing plate structure emits light in response to electrons emitted from the other plate structure. As electrons travel from the electron-emitting plate structure to the light-emitting plate structure, the laterally separated segments of the face electrode typically cause the electrons to be deflected in such a manner as to compensate for other electron deflection caused by the spacer. By suitably choosing the location and size of the electrode segments, the net electron deflection caused by the spacer can be quite small.

The segments of the face electrode normally reach electric potentials largely determined by resistive characteristics of the spacer. Although the potential along the spacer generally increases in going from the electron-emitting plate structure to the light-emitting plate structure, the potential is largely constant along each electrode segment. The effect of this constant potential produces the compensatory electron deflection.

Division of the face electrode into multiple laterally separated segments facilitates achieving appropriate compensatory electron deflection along the entire active-region length of the spacer, the spacer's length being measured laterally, generally parallel to the plate structures. In particular, the value of electric potential that each electrode segment needs to attain in order to cause the requisite amount of compensatory electron deflection varies with distance from the plate structures in approximately the same way that the resistive characteristics of the spacer cause the segment potential to vary with distance from the plate structures. Once the desired segment potential is established for one distance from the plate structures, the distance from each segment to the plate structures can vary somewhat without significantly affecting the amount of compensatory electron deflection.

In contrast, consider what would happen if (a) a non-segmented face electrode were substituted for the present segmented face electrode and (b) the non-segmented face electrode were placed in approximately the same position over the main spacer portion as the segmented face electrode. The entire non-segmented face electrode would be at substantially a single electric potential. If the non-segmented face electrode were tilted relative to the plate structure for some reason, e.g., due to fabrication mis-alignment, one vertical slice through the non-segmented face electrode might be at largely the correct potential. However, a vertical slice anywhere else through the non-segmented face electrode would normally be at a wrong potential, leading to a wrong amount of compensatory electron deflection. Segmentation of the face electrode in the present flat-panel display provides tolerance in positioning the electrode segments to achieve the desired compensatory electron deflection across substantially all the active-region length of the spacer, thereby overcoming the lack of positioning tolerance that would occur with a non-segmented face electrode.

The amount of compensatory electron deflection caused by each segment of the present face electrode depends on the segment's width. Accordingly, the widths of the electrode segments normally need to be controlled well.

In applying the invention's teachings to the fabrication of a flat-panel display, particularly one of the CRT type, a masking step is typically utilized in defining the widths of the segments of the face electrode. In general, better dimensional control can be achieved with a masking operation, especially photolithographic masking as is normally utilized to implement the masking step, than with a mechanical cutting operation as employed conventionally by Schmid et al to define the widths of the face electrodes in U.S. Pat. No. 5,675,212. The net electron deflection arising from the presence of a spacer can thus more uniformly be made closer to zero in the invention than in Schmid et al. The invention substantially alleviates the associated image degradation that can arise in the prior art.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1 and 2

are schematic cross-sectional side views of part of a conventional flat-panel CRT display. The cross section of

FIG. 1

is taken through plane

1

—

1

in FIG.

2

. The cross section of

FIG. 2

is taken through plane

2

—

2

in FIG.

1

.

FIGS. 3 and 4

are cross-sectional side views of part of a flat-panel CRT display configured according to the invention. The cross section of

FIG. 3

is taken through plane

3

—

3

in FIG.

4

. The cross section of

FIG. 4

is taken through plane

4

—

4

in FIG.

3

.

FIG. 5

is a graph of electric potential as a function of vertical distance at various locations in the flat-panel display of

FIGS. 3 and 4

.

FIGS. 6

a

-

6

d

are cross-sectional side views representing steps in a process for manufacturing a spacer suitable for the flat-panel display of

FIGS. 3 and 4

.

FIGS. 7 and 8

are cross-sectional side views of part of another flat-panel CRT display configured according to the invention. The cross section of

FIG. 7

is taken through plane

7

—

7

in FIG.

8

. The cross section of

FIG. 8

is taken through plane

8

—

8

in FIG.

7

.

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

Subject to the comments given in the following paragraph about certain types of thin coatings, the term “electrically resistive” generally applies here to an object, such as a plate or a main portion of a spacer, having a sheet resistance of 10

10

-10

13

ohms/sq. An object having a sheet resistance greater than 10

13

ohms/sq. is generally characterized here as being “electrically insulating” (or “dielectric”). An object having a sheet resistance less than 10

10

ohms/sq. is generally characterized here as being “electrically conductive”.

A thin coating, whether a blanket coating or a patterned coating, formed over an electrically resistive main portion of a spacer is characterized here as “electrically resistive”, “electrically insulating”, or “electrically conductive” depending on the relationship between the sheet resistance of the coating and the sheet resistance of the main spacer portion. The coating is “electrically resistive” when its sheet resistance is from 10% to 10 times the sheet resistance of the underlying main spacer portion. The coating is “electrically insulating” when its sheet resistance is greater than 10 times the sheet resistance of the main spacer portion. The coating is “electrically conductive” when its sheet resistance is less than 10% of the sheet resistance of the main spacer portion.

The term “electrically non-insulating” applies to an object, including a thin coating, that is electrically resistive or electrically conductive. For example, an object having a sheet resistance of no more than 10

13

ohms/sq. is generally characterized here as “electrically non-insulating”. The term “electrically non-conductive” similarly applies to an object that is electrically resistive or electrically insulating. An object having a sheet resistance of at least 10

10

ohms/sq. is generally characterized here as “electrically non-conductive”. These electrical categories are determined at an electric field of no more than 10 volts/μm.

A spacer situated between a backplate structure and a faceplate structure of a flat panel CRT display as described below typically consists of (a) a main spacer portion, (b) a pair of end electrodes that respectively contact the backplate and faceplate structures, and (c) one or more face electrodes. The end electrodes extend along opposite ends (or end surfaces) of the main spacer portion. If these two opposite ends of the main spacer portion are also edges as arises when the main spacer portion is shaped like a wall, the end electrodes can also be termed edge electrodes. Each face electrode extends along a face (or face surface) of the main spacer portion and is normally spaced apart from both end electrodes.

The spacer has two electrical ends, referred to here generally as the backplate-side and faceplate-side electrical ends, in the immediate vicinities of where the end electrodes respectively contact the backplate and faceplate structures. The positions of the spacer's two electrical ends relative to the physical ends of the spacer at the two end electrodes are determined as follows for the case in which each face electrode is spaced apart from both end electrodes. Firstly, when an end electrode extends along substantially an entire end of the main spacer portion, the corresponding electrical end of the spacer occurs at that end electrode and thus is coincident with the corresponding physical end of the spacer. Secondly, should an end electrode extend along only part of an end of the main spacer portion, the corresponding electrical end of the spacer is moved beyond the physical end of the spacer by a resistively determined amount. Specifically, the spacer (including both the end and face electrodes) has a resistance approximately equal to that of a vertically wider (or taller) spacer having an end electrode that extends along the entire spacer end in question. The difference in physical width (or height) between the two spacers, i.e., the one having the abbreviated end electrode and the longer one having the full end electrode, is the distance by which the indicated electrical end of the spacer with the abbreviated end electrode is moved beyond the physical end of that spacer.

In some embodiments of a flat-panel display configured according to the invention, a face electrode may contact an end electrode. When this occurs, the corresponding electrical end of the spacer is moved up the spacer toward the other end electrode by a resistively determined amount. Should a face electrode contact an end electrode that extends along only part of the end of the main spacer portion, the corresponding electrical end of the spacer is either moved up the spacer toward the other end electrode, or beyond the spacer, by a resistively determined amount depending on various factors. The distance by which the electrical and physical ends of the spacer differ in these two cases is determined according to the technique described in the previous paragraph.

FIGS. 3 and 4

, taken perpendicular to each other, schematically illustrate an active-region part of a flat-panel CRT display having a spacer system configured according to the invention. The flat-panel CRT display of

FIGS. 3 and 4

can serve as flat-panel television or a flat-panel video monitor suitable for a personal computer, a lap-top computer or a work station. In discussing the electrical capabilities of this flat-panel display, electric potentials are generally surface potentials, including work functions, rather than voltage supply potentials.

The flat-panel display of

FIGS. 3 and 4

includes a backplate structure

40

, a faceplate structure

42

, and a spacer system situated between plate structures

40

and

42

. The spacer system consists of a group of laterally separated spacers

44

. In the example of

FIGS. 3 and 4

, each spacer

44

is roughly shaped like a wall.

The display of

FIGS. 3 and 4

also includes an annular outer wall (not shown) situated between plate structures

40

and

42

to form a sealed enclosure in which spacers

44

are situated. The sealed enclosure is held at low pressure, typically 10

−7

torr or less. The spacer system formed with spacers

44

resists external forces, such as air pressure, exerted on the display

7

and maintains a relatively uniform spacing between plate structures

40

and

42

.

Backplate structure

40

contains an array of rows and columns of laterally separated regions

46

that selectively emit electrons in response to suitable control signals. Each electron-emissive region

46

typically consists of multiple electron-emissive elements. Regions

46

overlie a flat electrically insulating backplate (not separately shown). Further information on typical implementations of electron-emissive regions

46

is 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 the contents of which are incorporated by reference herein.

Backplate structure

40

also includes a primary structure

48

which is raised relative to electron-emissive regions

46

. That is, primary structure

48

extends further away from the exterior surface of backplate structure

40

than regions

46

. Structure

48

is typically configured laterally in a waffle-like pattern. Regions

46

are exposed through openings,

50

in structure

48

.

Primary structure

48

is typically a system that focuses electrons emitted from electron-emissive regions

46

. For this purpose, electron-focusing system

48

consists of an electrically non-conductive base focusing structure

52

and an electrically conductive focus coating

48

that lies on top of base focusing structure

52

and extends onto its sidewalls. In the example of

FIGS. 3 and 4

, focus coating

48

extends only partway down the sidewalls of focusing structure

52

and is therefore spaced apart from electron-emissive regions

46

. Alternatively, focus coating

54

can extend fully down the sidewalls of structure

52

provided that coating

54

is spaced apart from regions

46

. In either case, focus coating

54

receives a low electron-focusing potential V

L

, normally constant, during display operation.

Faceplate structure

42

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

56

respectively corresponding to electron-emissive regions

46

. Light-emissive elements

56

typically phosphor, overlie a transparent electrically insulating faceplate (not separately shown). Upon being struck by electrons selectively emitted from electron-emissive regions

46

, light-emissive regions

56

emit light to produce an image on the exterior surface of faceplate structure

42

.

The flat-panel display of

FIGS. 3 and 4

may be a black-and-white or color display. In the black-and-white case, each light-emissive region

56

and corresponding electron-emissive region

46

form a picture element (pixel). For a color display each light-emissive element

56

and corresponding electron-emissive region

46

form a sub-pixel. A color pixel consists of three adjoining sub-pixels, one for red, another for green, and the third for blue. The display has an active region defined by the lateral extent of the pixels.

Faceplate structure

42

further includes an electrical conductive anode layer

58

. In the example of

FIGS. 3 and 4

, anode layer

58

is a light reflector that lies on top of light-emissive elements

56

and extends into the generally waffle-shaped region that laterally separate elements

56

. This waffle-shaped region of faceplate structure

42

normally includes a “black” matrix that underlies anode layer

58

. During display operation, anode layer

58

reflects back some of the rear-directed light to increase the image intensity. Alternatively, light-reflective anode layer

58

can be replaced with a transparent electrically conductive layer that underlies light-emissive elements

56

. In either case, the anode layer receives a high anode potential V

H

, normally constant, during display operation. Anode potential V

H

is typically 4-10 kilovolts and is typically approximately this amount above focus potential V

L

.

Wall-shaped spacers

44

extend laterally in the row direction, i.e., along the rows of electron-emissive regions

46

or light-emissive elements

56

. The row direction extends into the plane of FIG.

3

and horizontally in FIG.

4

. The length of each spacer

44

is measured in the row direction. The width (or height) of each spacer

44

is measured vertically in

FIGS. 3 and 4

, i.e., from backplate structure

40

to faceplate structure

42

, or vice versa. As indicated in

FIG. 3

, spacers

44

are laterally separated by more than two rows of regions

46

(or elements

56

). In a typical implementation, thirty rows of regions

46

separate consecutive spacers

44

.

Each spacer

44

consists of an electrically resistive main spacer portion

60

, an electrically conductive backplate-side end electrode

62

, an electrically conductive faceplate-side end electrode

64

, and a laterally segmented electrically conductive face electrode

66

. Main spacer portion

60

is typically shaped as a wall that extends at least across the active region of the display. The width (or height), measured vertically, of main spacer wall

60

is 0.3-2.0 mm, typically 1.25 mm. The thickness of main wall

60

is 40-100 μm, typically 50-60 μm. Main wall

60

consists of electrically resistive material and possibly electrically insulating material so distributed within wall

60

that the overall nature of wall

60

is electrically resistive from its top end to its bottom end.

Each main wall

60

can be internally configured in various ways. Main wall

60

can be formed as one layer or as a group of laminated layers. In a typical embodiment, wall

60

consists primarily of a wall-shaped substrate formed with electrically resistive material whose sheet resistance is relatively uniform at a given temperature such as standard temperature (0° C.) Alternatively, wall

60

can be formed as an electrically insulating wall-shaped substrate covered on both substrate faces with an electrically resistive coating of relatively uniform sheet resistance at a given temperature. The thickness of the resistive coating is typically in the vicinity of 0.1 μm. In either case, resistive material of wall

60

extends continuously along the entire width of wall

60

.

Also, the resistive material of main wall

60

is typically covered on both faces with a thin electrically non-conductive coating that inhibits secondary emission of electrons. The secondary-emission-inhibiting coating typically consists of electrically resistive material. Specific examples of the constituency of main wall

16

are presented in Schmid et al, U.S. Pat. No. 5,675,212, also cited above, Spindt et al, U.S. Pat. No. 5,614,781, Spindt et al, U.S. Pat. No. 5,532,548, and Spindt et al, U.S. patent application Ser. No. 08/883,409, filed Jun. 26, 1997 now U.S. Pat. No. 5,872,424.

End electrodes

62

and

64

of each spacer

44

are situated on opposite ends of main spacer wall

60

and typically extend along the entirety of those two wall ends. Backplate-side end electrode

62

contacts backplate structure

40

along the top of focusing system

48

, specifically the top surface of focus coating

54

. Faceplate-side end electrode

64

contacts faceplate structure

42

along anode layer

58

in the waffle-like recession between light-emissive elements

56

. The thickness of end electrodes

62

and

64

is 50 nm-1 μm, typically 100 nm. End electrodes

62

and

64

typically consist of metal such as aluminum, chromium, nickel, or a nickel-vanadium alloy.

Main spacer wall

60

of each spacer

44

has two opposing faces. Face electrode

66

lies on one of these faces spaced apart from end electrodes

62

and

64

. Consequently, face electrode

66

is physically and electrically spaced apart from both of plate structures

40

and

42

. Face electrode

66

extends laterally along the length of main wall

60

. Face electrode

66

, is at least approximately a quarter of the way from backplate structure

40

to faceplate structure

42

. That is, without having electrode

66

electrically touch faceplate structure

42

, the minimum distance from backplate structure

40

to electrode

66

is approximately one fourth of the distance between plate structures

40

and

42

. Normally, electrode

66

is somewhat closer to structure

42

than structure

40

. The thickness of electrode

66

is 50 nm-1 μm, typically 100 nm. Electrode

66

typically consists of metal such as aluminum, chromium, nickel, or a nickel-vanadium alloy.

Focusing system

48

provides highly advantageous locations for spacers

44

to contact backplate structure

40

. However, for the reasons discussed below, electrons emitted from electron-emissive regions

46

, especially regions

46

directly adjacent to spacers

44

, are deflected away from the nearest spacers

44

due to the way in which spacers

44

are arranged relative to plate structures

40

and

42

, particularly backplate structure

40

. The presence of face electrodes

66

causes the electrons to be deflected back towards the nearest spacers

44

to compensate for the deflection away from the nearest spacers

44

. The net electron deflection is close to zero.

To accurately provide the compensatory electron deflection, face electrode

66

of each spacer

44

is divided into N electrode segments

66

1

,

66

2

, . . .

66

N

.

FIG. 4

depicts seven electrode segments

66

1

-

66

7

, N thereby being at least

7

. Electrode segments

66

1

-

66

N

are spaced laterally apart from one another. That is, as viewed in the lateral direction perpendicular to main spacer wall

60

or as viewed in the vertical direction from backplate structure

40

to faceplate structure

42

(or vice versa), electrode segments

66

1

-

66

N

are laterally separated. Segments

66

1

-

66

N

are arranged generally in a line extending in the row direction parallel to the exterior surface of backplate structure

40

. Electrode segments

66

1

-

66

N

extend across substantially all the active-region length of wall

60

.

Electrode segments

66

1

-

66

N

of each spacer

44

are all typically of substantially the same size and shape. In the example of

FIG. 3

, segments

66

1

-

66

N

are shown as equal-size rectangles. For the rectangular case, each segment

66

i

has a width w

Fi

, measured vertically, of 50-500 μm, typically 70 μm, where i is an integer varying from 1 to N. Each segment

66

i

in the rectangular case has a length, measured laterally in the row direction, of 100 μm-2 mm, typically 300 μm. The lateral separation between consecutive ones of segments

66

1

-

66

N

is 5-50 μm, typically 25 μm. Segments

66

1

-

66

N

can have various other shapes such as ellipses (including circles), diamonds, trapezoids, and so on. Both the size and shape of segments

66

1

-

66

N

can vary from segment

66

i

to segment

66

i

of each spacer

44

.

Electrode segments

66

1

-

66

N

“float” electrically. In other words, none of segments

66

1

-

66

N

is directly connected to an external voltage source. Each segment

66

i

reaches an electric potential V

Fi

determined by resistive characteristics of spacer

44

, particularly main spacer wall

60

. Although segments

66

i

-

66

N

in

FIG. 4

are arranged generally in a line extending parallel to the exterior surface of backplate structure

40

, the line may not be exactly straight. The line of segments

66

1

-

66

N

may also be slanted slightly relative to the exterior backplate surface. As a consequence, potential V

Fi

achieved by one segment

66

i

may differ from potential V

Fi

achieved by another segment

66

i

.

Electric potential V

Fi

of each electrode segment

66

i

of each spacer

44

normally penetrates largely through its main spacer wall

60

to the mirror-image location on the face of main wall

60

opposite the face having face electrode

66

. Specifically, segment potential V

Fi

penetrates largely through wall

60

when it consists entirely of electrically resistive material. Due to the electric potential penetration through wall

60

, it is usually unnecessary to provide a segmented face electrode on the opposite wall face at a location corresponding to electrode

66

. Nonetheless, such an additional segmented face electrode can be provided on the opposite wall face. Also, when any intervening electrically insulating material is thick enough to significantly inhibit the electric potential penetration through wall

60

, an additional segmented face electrode generally matching electrode

66

is normally placed on the wall face opposite that having electrode

66

.

An understanding of the corrective electron-deflection function performed by segmented face electrode

66

involves the following electrical considerations. Referring to

FIG. 3

, the electron-emissive elements in regions

46

emit electrons generally from an emission-site plane

70

extending generally parallel to the exterior surface of backplate structure

40

. Emission-site plane

70

is slightly below the upper surface of electron-emissive regions

46

.

Backplate structure

40

has an electrical end located in a backplate-structure electrical-end plane

72

extending parallel to emission-site plane

70

at a distance d

L

away from emission-site-plane

70

. The electrical end of backplate structure

40

is the approximate planar location at which the interior surface of structure

40

appears to terminate electrically as viewed from a long distance away. Local differences in the topography of the interior surface of structure

40

are electrically averaged out in determining its electrical end. As discussed below, the position of backplate-structure electrical-end plane

72

moves up and down slightly during display operation depending on the potentials applied to electron-emissive regions

46

.

The top of focus coating

54

is at a distance d

S

above emission-site plane

70

. Distance d

S

is normally 20-70 μm, typically 40-50 μm. Distance d

L

to backplate-structure electrical-end plane

72

is normally less than distance d

S

. Distance d

L

is positive in the example of

FIG. 3

in which electrical-end plane

72

overlies emission-site plane

70

. In some embodiments, distance d

L

can be negative so that electrical-end plane

72

lies below emission-site plane

70

.

Spacers

44

have backplate-side electrical ends located in a backplate-side spacer electrical end plane

74

extending parallel to emission-site plane

70

. Since backplate-side end electrodes

62

fully cover the backplate-side edges of main spacer walls

60

, the backplate-side electrical ends of spacers

44

are coincident with their backplate-side physical ends at end electrodes

62

. Hence, backplate-side spacer electrical-end plane

74

is located largely at distance d

S

above emission-site plane

70

. Because distance d

L

is less than distance d

S

, the backplate-side electrical end of each spacer

44

is situated above electrical-end plane

72

in which the electrical end of backplate structure

40

is located. This separation between backplate-structure electrical-end plane

72

and the backplate-side electrical end of each spacer

44

affects the potential field along spacers

44

near backplate structure

40

in such a way that electrons emitted from nearby electron-emissive regions

46

are initially deflected away from the nearest spacers

44

.

In a similar manner, faceplate structure

42

has an electrical end located in a faceplate-structure electrical-end plane

76

extending parallel to emission-site plane

70

at a distance d

H

above plane

70

. The electrical end of faceplate structure

42

is the approximate planar location at which the interior surface of structure

42

along anode layer

58

appears to terminate electrically as viewed from a long distance away.

Spacers

44

have faceplate-side electrical ends located in a faceplate-side spacer electrical-end plane

78

extending parallel to emission-site plane

70

at a distance d

T

above plane

70

. With faceplate-side end electrodes

64

fully covering the faceplate-side edges of main spacer walls

60

, the faceplate-side electrical ends of spacers

44

are coincident with their faceplate-side physical ends at end electrodes

64

. Since spacers

44

extend into the waffle-like recession between light-emissive elements

56

, the faceplate-side electrical end of each spacer

44

is spaced apart from faceplate-structure electrical-end plane

76

.

More particularly, relative to backplate structure

40

, the faceplate-side electrical ends of spacers

44

are situated above faceplate-structure electrical-end plane

76

. The effect of this geometry is to cause electrons emitted from regions

46

to be deflected away from nearest spacers

44

. Face electrodes

66

cause the potential field along spacers

44

to be perturbed in such a way as to compensate for electron deflection away from nearest spacers

44

caused by the faceplate-side electrical ends of spacers

44

being above faceplate-structure electrical-end plane

76

as well as electron deflection away from nearest spacers

44

caused by the backplate-side electrical ends of spacers

44

being located above backplate-structure electrical-end plane

72

.

Alternatively, relative to backplate structure

40

, the faceplate-side electrical ends of spacers

44

could be situated below faceplate-structure electrical-end plane

76

. Such a configuration would cause electrons emitted from regions

46

to be deflected toward nearest spacers

44

, thereby reducing the amount of compensatory electron deflection that face electrodes

66

need to cause.

FIG. 5

is a graph that qualitatively illustrates the electric potential field at various locations in the flat-panel display of FIG.

3

. This graph is helpful in understanding how spacers

44

, including segmented face electrodes

66

, affect the movement of electrons from backplate structure

40

to faceplate structure

42

. The graph of

FIG. 5

is also helpful in understanding how distances d

L

and d

H

are determined and, consequently, how the electrical ends of plate structures

40

and

42

are determined.

More particularly,

FIG. 5

illustrates how electric potential varies with distance along vertical lines

80

,

82

, and

84

in FIG.

3

. In

FIG. 5

, vertical distance is zero at emission-site plane

70

. Curves

80

*,

82

*, and

84

* in

FIG. 5

respectively represent the electric potentials along lines

80

,

82

, and

84

. As discussed below, potential curves

80

* and

84

* converge in the space between plate structures

40

and

42

. This convergence is represented by common potential curve

86

in FIG.

5

.

Referring to

FIG. 3

, vertical line

80

originates along emission-site plane

70

at an electron-emissive region

46

separated by at least one row of regions

46

from the nearest spacer

44

. Line

80

terminates at a portion of anode layer

58

overlying the corresponding light-emissive element

56

. Accordingly, line

80

extends from a vertical distance of zero to a vertical distance of d

H

.

Vertical line

82

extends along one face of main spacer portion

60

of left-hand spacer

44

in

FIG. 3

from a top portion of focus coating

54

to a portion of anode layer

58

situated in the recession between light-emissive elements

56

. In the example of

FIG. 3

, line

82

passes through face-electrode segment

66

3

of left-hand spacer

44

. Alternatively, line

82

could extend along the opposite face of main spacer portion

60

of left-hand spacer

44

. In that case, corresponding potential curve

82

* would appear basically the same as shown in

FIG. 5

except that the flat area corresponding, as indicated below, to face-electrode segment

66

3

would be rounded downward to the left and upward to the right.

Vertical line

84

originates at a top portion of focus coating

54

separated by at least one row of electron-emissive regions

46

from the nearest spacer

44

, and terminates at a portion of anode layer

58

situated in the recession between light-emissive elements

56

. Lateral-wise, lines

82

and

84

originate at points spaced largely equal lateral distances away from the edges of the underlying portions of focus coating

54

. Each of lines

82

and

84

extends from a vertical distance of d

S

to a vertical distance of d

T

.

The electrical end of backplate structure

40

at electrical-end plane

72

is defined with reference to an equipotential surface at V

L

, the low focus potential applied to focus coating

54

. For exemplary purposes in determining the location of the electrical end of backplate structure

40

, the potential along plane

70

where regions

46

emit electrons is taken to be V

L

in FIG.

5

. The equipotential surface at potential V

L

in the example of

FIG. 5

thus extends through focus coating

54

and through the portions of plane

70

at electron-emissive regions

46

.

With the foregoing in mind, electric potential

80

* along vertical line

80

increases from low focus value V

L

at a vertical distance of zero to high anode value V

H

at a vertical distance between d

H

and d

T

. Electric potential

84

* along vertical line

84

increases from low value V

L

at distance d

S

to high value V

H

at distance d

T

. Reference symbols

88

and

90

in

FIG. 5

respectively indicate the end points of potential curve

84

* at vertical distances d

S

and d

T

. As the distance away from plate structures

40

and

42

increases, potentials

80

* and

84

* converge to potential

86

that varies linearly with increasing vertical distance, i.e., curve

86

is a straight line.

Dashed straight line

86

L in

FIG. 5

is an extrapolation of straight line

86

to low value V

L

on the horizontal axis. Straight line

86

L reaches V

L

at distance d

L

, thereby defining the electrical end of backplate structure

40

. In essence, distance d

L

is the average distance electrically to the backplate-side equipotential surface, primarily focus coating

54

here, at low potential V

L

. During display operation, the portions of the V

L

equipotential surface at the locations of electron-emissive regions

46

move upward and downward depending on the potentials applied to each region

46

. This movement of the V

L

equipotential surface causes the electrical end of backplate structure

40

to move slightly upward and downward during display operation, typically less than 1 μm. One primary reason for the movement of the electrical end of backplate structure

40

being so small here is that the ratio of distance d

L

to the column-direction spacing between consecutive regions

46

is (comparatively) large in the display of

FIGS. 3 and 4

.

Similarly, dashed straight line

86

H in

FIG. 5

is an extrapolation of straight line

86

upward to high value V

H

. Straight line

86

H reaches V

H

at distance d

H

, thereby defining the electrical end of faceplate structure

42

. Distance d

H

is the average distance electrically to the faceplate-side equipotential surface (anode layer

58

) at high potential V

H

. The electrical end of faceplate structure

42

is substantially stationary during display operation.

Each face-electrode segment

66

i

is located at an average vertical distance d

Fi

above emission-site plane

70

. In other words, distance d

Fi

is the vertical distance to half the width w

Fi

of segment

66

i

.

FIG. 3

illustrates distance d

F3

and width w

F3

for segment

66

3

. Let d

FBi

and d

FTi

respectively represent the vertical distances from plane

70

to the bottom and top of segment

66

i

. Bottom distance d

FBi

then equals d

Fi

−w

Fi

/2.

868

Top distance d

FTi

equals d

Fi

+w

Fi

/2.

As mentioned above, vertical line

82

passes through face-electrode segment

66

3

of left-hand spacer

44

. However, line

82

could as well be a vertical line passing through any other face-electrode segment

66

i

of that spacer

44

. For the sake of generality, potential

82

* on line

82

is hereafter treated here as being the potential on a vertical line passing through any electrode segment

66

i

of left-hand spacer

44

.

Potential curve

82

* originates from the same starting condition at point

88

as potential curve

84

*, i.e., from low value V

L

at distance d

S

. Except near backplate structure

40

and face-electrode segment

66

i

, potential

82

* increases from this starting condition in a generally linear manner as a function of vertical distance to face-electrode potential V

Fi

at distance d

FBi

. The approximately linear variation of potential

82

* with vertical distance from d

S

to d

FBi

occurs because the sheet resistance of main spacer portion

60

is approximately constant along the width (or height) d

T

−d

S

of spacer portion

60

at a given temperature. In going from low value V

L

to face-electrode potential V

Fi

, curve

82

* crosses the common portion

86

of curves

80

* and

84

* at a point

92

.

Potential

82

* stays substantially constant at V

Fi

across electrode segment width w

Fi

from distance d

FBi

to distance d

FTi

. In so doing, curve

82

* again crosses common portion

86

of curves

80

* and

84

*, this time at a point

94

. As indicated in

FIG. 5

, point

94

occurs at distance d

Fi

approximately halfway across segment width w

Fi

.

Except near face-electrode segment

66

i

and faceplate structure

42

, potential

82

* increases in a generally linear manner from face-electrode potential V

Fi

at distance d

FTi

to high value V

H

at distance d

T

, thereby terminating at the same ending condition at point

90

as potential

84

*. The approximately linear variation of potential

82

* with vertical distance from d

Fi

to d

T

occurs because the sheet resistance of main spacer portion

60

is approximately constant along its width at a given temperature. Except near electrode segment

66

i

and plate structures

40

and

42

, the slope of curve

82

* across the d

FTi

−d

T

region closely approximates the slope of curve

82

* across the d

S

−d

FBi

region.

When the electrical ends of a spacer, such as any of spacers

44

, in a flat-panel CRT display are not respectively coincident with the electrical ends of the display's backplate and faceplate structures, the electric potential field along at least part of the surface of the spacer invariably differs from the electric potential field that would exist at the same location in free space between the backplate and faceplate structures, i.e., in the absence of the spacer. The trajectories of electrons moving from the backplate structure to the faceplate structure in the proximity of the spacer are affected differently by the so-modified potential field along the spacer then by the potential field that would exist at the same location in free space between the two plate structures. Consequently, the spacer affects the electron trajectories.

Spacers

44

, including segmented face electrodes

66

, affect the trajectories of electrons emitted from electron-emissive regions close to spacers

44

by compensating for undesired electron deflection that arises because the electrical ends of spacer

44

are spaced apart from the electrical ends of plate structures

40

and

42

. In particular, the backplate-side electrical ends of spacers

44

are situated in electrical-end plane

74

at distance d

S

and thus are located above the electrical end of backplate structure

40

at distance d

L

. The non-matching of the backplate-side electrical ends of spacers

44

to the electrical ends of backplate structure

40

generally causes the potential field along spacers

44

near structure

40

to be more negative (lower) in value than what would occur if the backplate-side electrical ends of spacer

44

were located in backplate-structure electrical end plane

72

and thereby matched to the electrical end of structure

40

. As a result, electrons emitted from electron-emissive regions

46

close to spacers

44

are initially deflected away from the nearest spacers

44

. Face electrodes

66

compensate for these initial undesired electron deflections by causing the electrons to be deflected back towards the nearest spacers

44

.

Similarly, relative to backplate structure

40

, the faceplate-side electrical ends of spacers

44

are situated in electrical-end plane

78

at distance d

T

and thus are located above faceplate-structure electrical-end plane

76

at distance d

H

. The non-matching of the faceplate-side electrical ends of spacers

44

to the electrical end of faceplate structure

42

causes the potential field along spacers

44

near structure

42

to be more negative in value than what would occur if the faceplate-side electrical ends of spacers

44

were located in plane

76

and thus matched to the electrical end of structure

42

. This causes electrons emitted from regions

46

to be deflected away from nearest spacers

44

. Face electrodes

66

also compensate for this undesired electron deflection by causing electron deflection back towards the nearest spacers

44

.

Face electrode

66

of each spacer

44

provides the deflection compensation in the following manner. As mentioned above, potential curves

82

* and

84

* originate from the same condition at point

88

and terminate at the same condition at point

90

. This occurs because vertical lines

82

and

84

originate at corresponding locations relative to the top of focus coating

54

. In effect, curve

84

* represents the potential that would exist along line

82

in free space between plate structures

40

and

42

, i.e., in the absence of spacers

44

.

With anode potential V

H

exceeding the potential along emission-site plane

70

, electrons emitted by electron-emissive regions

46

accelerate in traveling from backplate structure

40

to faceplate structure

42

. Hence, the emitted electrons move faster near faceplate structure

42

than near backplate structure

40

. Slower moving electrons are attracted or repelled more in response to the potential field near spacers

44

than faster moving electrons.

If face electrodes

66

were absent from spacers

44

, the resulting potential along vertical line

82

next to so-modified left-hand spacer

44

in

FIG. 3

would vary from point

88

to point

90

in

FIG. 5

in an approximately linear manner with increasing vertical distance as represented by straight dashed line

96

in FIG.

5

. In the illustrated example, electric potential

96

is always more negative in value than electric potential

84

* (except at end points

88

and

90

). In the absence of face electrodes

66

, the potential at the surface of so-modified left-hand spacer

44

would cause electrons emitted from nearby electron-emissive regions

46

, especially the two regions

46

nearest left-hand spacer

44

, to be deflected away from it. This would occur even if the faceplate side of the display were modified so that curve

96

crosses curve

84

* at a vertical distance corresponding to a point in the vicinity of one quarter of the way (or more) up the height of left-hand spacer

44

.

With face electrodes

66

present, curve

82

* crosses curve

84

* at points

92

and

94

. Between points

88

and

92

, potential

82

* is more negative in value than potential

84

*. Consequently, electrons emitted from nearby electron emissive regions

46

, especially the two regions

46

nearest to left-hand spacer

44

, are deflected away from that spacer

44

due to the potential field experienced in traveling from the vertical distance at point

88

to the vertical distance at point

92

. Although potential

82

* is more negative in value than potential

84

*, potential

82

* is relatively close to potential

84

*. The electron deflection away from left-hand spacer

44

due to the potential field in the lower region demarcated by points

88

and

92

is thus relatively small.

Between points

92

and

94

, potential

82

* is more positive (higher) in value than potential

84

*, here represented by common potential

86

. The electrons emitted from nearby electron-emissive regions

46

thereby undergo corrective electron deflections towards left-hand spacer

44

due to the potential field experienced in traveling from the vertical distance at point

92

to the vertical distance at point

94

. As

FIG. 5

illustrates, the area between curves

82

* and

84

* in the intermediate region demarcated by points

88

and

92

is considerably greater than the area between curves

84

* and

82

in the lower region demarcated by points

88

and

92

. Even though electrons travel faster in the intermediate region than in the lower region, the electron deflection towards left-hand spacer

44

due to the potential field in the intermediate region is significantly greater than the electron deflection away from that spacer

44

due to the potential field in the lower region. The magnitude of the area between curves

82

* and

84

* in the intermediate region, and thus the magnitude of the corrective electron deflection towards left-hand spacer

44

, is determined by width w

Fi

of each face-electrode segment

66

i

of that spacer

44

.

Between points

94

and

90

, potential

82

* is again more negative in value than potential

84

*. Consequently, electrons emitted from nearby electron-emissive region

46

are deflected away from left-hand spacer

44

due to the potential field experienced in traveling from the vertical distance at point

94

to the vertical distance at point

90

. The electrons reach their greatest velocity in the upper region demarcated by points

94

and

90

, and thus are less affected by unit changes in potential

82

* in the upper region than by unit changes in potential

82

* in the intermediate region demarcated by points

92

and

94

. With the mean value of face-electrodes segment width w

Fi

exceeding some specified minimum value and with each face-electrode-segment

66

i

being located at least approximately one fourth of the distance from backplate structure

40

to faceplate structure

42

, the net result is that face electrode

66

causes electrons emitted from nearby electron-emissive regions

46

to be deflected towards left-hand spacer

44

.

By appropriately choosing suitable mean values for segment widths w

Fi

and average segment distances d

Fi

, the electron deflections toward spacers

44

correct for the undesired electron deflections away from spacers

44

due to the backplate-side electrical ends of spacers

44

being above the electrical end of backplate structure

40

and due to the faceplate-side electrical ends of spacers

44

being above the electrical end of faceplate structure

42

. Curved dotted line

98

in

FIG. 3

illustrates the trajectory of a typical electron emitted from one of the electron-emissive regions nearest to left-hand spacer

44

. As electron trajectory

98

indicates, the initial and final electron deflections away from left-hand spacer

44

are corrected by an intermediate deflection towards that spacer

44

so that the net electron deflection is close to zero.

The magnitude of the compensatory electron deflection caused by each face-electrode segment

66

i

depends on segment width w

Fi

and segment potential V

Fi

. The magnitude of the particular V

Fi

value that each electrode segment

66

i

needs to be at in order to achieve the right amount of corrective electron deflection generally increases with increasing segment distance d

Fi

.

As mentioned above, the resistive characteristics of spacers

44

determine face-electrode segment potentials V

Fi

. In particular, the magnitude of segment potential V

Fi

for each spacer

44

increases with increasing segment distance d

Fi

, and vice versa.

Importantly, the rate at which the resistive characteristics of each spacer

44

cause its V

Fi

magnitude to increase with increasing vertical distance is approximately the same as the rate at which the V

Fi

magnitude needs to increase with vertical distance to achieve the right amount of compensatory electron deflection. When the V

Fi

magnitude needed to achieve a desired compensatory electron deflection is determined for one selected value of distance d

Fi

, the amount of compensatory electron deflection caused by electrode segment

66

i

varies relatively slowly as distance d

Fi

is varied upward and downward from the selected d

Fi

value.

The value of segment potential V

Fi

needed to achieve a specific compensatory electron deflection can vary along the length, measured laterally, of electrode segment

66

i

if it is tilted. Although such tilting can lead to a compensation error along the length of a tilted segment

66

i

, the compensation error can be made quite small by making electrode segments

66

i

suitably short.

Importantly, the relative insensitivity of the deflection compensation to segment distance d

Fi

means that different ones of electrode segments

66

1

-

66

N

can be at different d

Fi

values without significantly affecting the magnitude of the deflection compensation along the length of face electrode

66

. While segments

66

1

-

66

N

are typically arranged in a straight line, each face electrode

66

can be tilted or curved in various ways.

The flat-panel display of

FIGS. 3 and 4

is manufactured in the following manner. Plate structures

40

and

42

and the outer wall (not shown) which laterally encloses spacers

44

and connects plate structures

40

and

42

together are separately manufactured. Spacers

44

are also separately manufactured. Components

40

,

42

, and

44

and the outer wall are assembled in such a way that the pressure inside the sealed display is quite low, normally no more than 10

−7

torr. In assembling the display, spacers

44

are inserted between plate structures

40

and

42

such that the backplate-side and faceplate-side ends of each spacer

44

respectively contact focus coating

54

and anode layer

58

at the desired locations.

Spacers

44

are normally fabricated by a process in which a masking operation is employed to define the shape of segmented face electrodes

66

. The masking operation enables segment width w

Fi

to be highly uniform from segment

66

i

to segment

66

i

. The fabrication of spacers

44

typically entail depositing a blanket layer of the material intended to form electrodes

66

and then selectively removing undesired portions of the blanket layer using a mask to define where the undesired material is to be removed. The mask can cover the electrode material that forms electrodes

66

or can be used to define the shape of a patterned lift-off layer which is provided below the blanket electrode-material layer and which is removed to lift off undesired electrode material. Alternatively, electrode

66

can be selectively deposited using a mask, typically referred to as a shadow mask, to prevent the electrode material from accumulating elsewhere.

FIGS. 6

a

-

6

d

(collectively “FIG.

6

”) illustrate how spacers

44

are fabricated using a blanket-deposition/selective-removal technique in which a mask covers the desired electrode material. The starting point for the process of

FIG. 6

is a generally flat sheet

100

of spacer material. See

FIG. 6

a

. Except for not being cut into main spacer portions

60

, sheet

100

contains the material(s) of main spacer portion

60

arranged the same thickness-wise as in main portions

60

.

A blanket layer

102

of the material that forms face electrodes

66

is deposited on sheet

100

as shown in

FIG. 6

b

. Blanket electrode layer

102

is of approximately the same thickness as electrodes

66

. A photoresist mask

104

configured laterally in the shape of at least one electrode

66

, typically multiple electrodes

66

, is formed on top of electrode layer

102

.

FIG. 6

b

illustrates the typical situation in which photoresist mask

104

is in the shape of multiple electrodes

66

. The exposed portions of electrode layer

102

are removed with a suitable etchant. Photoresist mask

104

is removed.

FIG. 6

c

shows the resultant structure in which the remaining portions of electrode layer

102

form multiple face electrodes

66

, two of which are depicted.

Sheet

100

is now cut into main spacer portions

60

by a process in which end electrodes

62

and

64

are formed over the backplate-side and faceplate-side ends of each spacer portion

60

. See

FIG. 6

d

. The fabrication of spacers

44

is complete. Spacers

44

are subsequently inserted between plate structures

40

and

42

during the display assembly process.

In using a lift-off procedure to create face electrode

66

, the starting point is the structure of

FIG. 6

a

. A blanket lift-off layer is deposited on top of sheet

100

. The lift-off layer is patterned in the reverse shape of electrodes

66

by forming a suitable photoresist mask on the lift-off layer, removing the uncovered lift-off material with a suitable etchant, and then removing the mask. A blanket layer of the face-electrode material is deposited on the remaining patterned lift-off layer and on the uncovered material of sheet

100

. The lift-off layer is then removed with a suitable etchant, thereby removing the overlying electrode material. The remainder of the electrode material forms face electrodes

66

.

When the shapes of segmented face electrodes

66

are defined by a shadow mask, the starting point for the fabrication process is again the structure of

FIG. 6

a

. The shadow mask is positioned above sheet

100

and has openings at the intended locations for electrode

66

. The face-electrode material is deposited over the shadow mask and into the openings to produce the structure of

FIG. 6

c

. Cutting of sheet

100

and formation of end electrodes

62

and

64

is conducted to produce spacers

44

as shown in

FIG. 6

d.

FIGS. 7 and 8

, taken perpendicular to each other, illustrate a variation of the flat-panel CRT display of

FIGS. 3 and 4

configured according to the invention. Except for the configuration of face electrodes formed on main spacer portions

60

of spacers

44

, the flat-panel display of

FIGS. 7 and 8

is configured the same as that of

FIGS. 3 and 4

. Aside from masking modifications needed to account for the different face-electrode configuration, the display of

FIGS. 7 and 8

is also fabricated in the same way as that of

FIGS. 3 and 4

.

In the flat-panel display of

FIGS. 7 and 8

, multiple laterally segmented electrically conductive face electrodes that extend laterally across the display's active region are situated on one face of main spacer

60

of each spacer portion

44

.

FIGS. 7 and 8

illustrate an example in which each spacer

60

contains three segmented electrically conductive face electrodes

110

,

112

, and

114

. Each of face electrodes

110

,

112

, and

114

is located at least approximately a quarter of the way from backplate structure

40

to faceplate structure

42

, face electrodes

110

and

114

being respectively closest to and furthest from faceplate structure

42

. Electrodes

110

,

112

, and

114

are normally somewhat closer to faceplate structure

42

than to backplate structure

40

. Electrodes

110

,

112

, and

114

consist of the same material as electrodes

66

. The thickness of each of electrodes

110

,

112

, and

114

is typically the same as that of electrodes

66

.

Each face electrode

110

is divided into N laterally separated segments

110

1

,

110

2

, . . .

110

N

. Each face electrode

112

is likewise divided into N laterally separated segments

112

1

,

112

2

, . . .

112

N

. Each electrode

114

is also divided into N laterally separated segments

114

1

,

114

2

, . . .

114

N

.

FIG. 8

depicts seven segments for each of electrodes

110

-

112

, and

114

, N thereby again being at least

7

. The lateral separation between electrode segments

110

1

-

110

N

, between electrode segments

112

1

-

112

N

, and between electrode segments

114

1

-

114

N

is typically the same as the lateral separation between electrode segments

66

1

-

66

N

.

Segments

110

1

-

110

N

are all typically of the same size and shape. The same applies to segments

112

1

-

112

N

and segments

114

1

-

114

N

. However, the size and shape of the segments in segment groups

110

1

-

110

N

,

112

1

-

112

N

, and

114

1

-

114

N

can differ from the size and shape of the electrodes in either or both of the other two of segment groups

110

1

-

110

N

,

112

1

-

112

N

, and

114

1

-

114

N

. Although segments

110

1

-

110

N

,

112

1

-

112

N

, and

114

1

-

114

N

are shown as rectangles in

FIG. 8

, they can have any of the other shapes mentioned above for electrode segments

66

1

-

66

N

.

Each electrode segment

110

i

is typically situated fully above electrode segment

112

i

. In turn, each electrode segment

112

i

is typically situated fully above electrode segment

114

i

. For the rectangular case, the composite width of segments

110

i

,

112

i

, and

114

i

is typically slightly greater than width w

Fi

.

As in the display of

FIGS. 3 and 4

, the non-matching of the electrical ends of spacers

44

to the electrical ends of plate structures

40

and

42

, especially the non-matching of the backplate-side electrical ends of spacers

44

to the electrical end of backplate structure

40

, in the display of

FIGS. 7 and 8

leads to undesired electron deflection away from the nearest spacers

44

. Each set of electrode segments

110

i

,

112

i

, and

114

i

typically functions in the same way as electrode segment

66

i

to cause electrons emitted from nearby electron-emissive regions

46

, especially the nearest regions

46

, to be deflected towards the closest spacers

44

. This compensates for the undesired electron deflection away from the nearest spacers

44

.

The width of each electrode segment

110

i

,

112

i

, or

114

i

invariably differs somewhat from the target (desired) width for that segment

110

i

,

112

i

, or

114

i

. The face-electrode configuration of

FIGS. 7 and 8

is particularly useful when there are uncorrelated, i.e., essentially random, errors in the widths of electrode segments

110

i

,

112

i

, and

114

i

. By having multiple segments

110

i

,

112

i

, and

114

i

, the uncorrelated errors tend to average out so that the actual composite width of each group of three segments

110

i

,

112

i

, and

114

, is relatively close to the composite target width for that group of three segments

110

i

,

112

i

, and

114

i

.

The errors in the widths of features created by a photolithographic masking procedure such as either of the blanket-depositions/selective-removal processes described above for manufacturing face electrodes

66

tend to be correlated. That is, when the actual width of one of the features is greater than, or less than, the target width for that feature, the actual width of each other of the features is typically greater than, or less than, the corresponding target width for that other feature by approximately the same amount.

In a variation of the flat-panel CRT display of

FIGS. 7 and 8

, only two of segmented face electrodes

110

,

112

, and

114

are present. For example, consider the case in which only segmented electrodes

110

and

114

are present. As in the display of

FIGS. 7 and 8

, upper segmented electrode

110

in this variation is at least approximately one quarter of the way from backplate structure

40

to faceplate structure

42

and is normally closer to faceplate structure

42

than backplate structure

40

. On the other hand, lower segmented electrode

114

in the variation is less than approximately one quarter of the way from backplate structure

40

to faceplate structure

42

. Due to this positioning of lower electrode

114

, it causes electrons to be deflected away from nearest spacers

44

. Upper electrode

110

thus has an additional duty. Besides producing electron deflection towards nearest spacers

44

to compensate for the non-matching of the electrical ends of each spacer

44

to the electrical ends of plate structures

40

and

42

, upper electrode

110

provides compensation for the electron deflection away from nearest spacers

44

due to the positioning of lower electrode

114

.

The magnitude of the electron deflection away from nearest spacers

44

due to the positioning of lower face electrode

114

is relatively small compared to the electron deflection towards nearest spacers

44

caused by upper face electrode

110

. This difference in deflection magnitude is achieved by suitable adjustment of the target widths of electrodes

110

and

114

. Importantly, when there are correlated errors in the widths of electrodes

110

and

114

, the error in the width of each upper electrode segment

110

i

approximately equals the error in the width of lower electrode segment

114

i

. These errors approximately cancel so that the difference between the actual width of upper segment

110

i

and the actual width of lower segment

114

i

is quite close to the difference between the target width of upper segment

110

i

and the target width of lower segment

114

i

. In other words, the actual difference in face-electrode segment width is quite close to the target difference in the face-electrode segment width even though errors occur in the widths of both segment

110

i

and segment

114

i

. By appropriately choosing the locations and target widths of electrodes

110

and

114

in this variation, excellent compensation for electron deflection is obtained.

The present flat-panel display typically operates in the following manner. With focus coating

54

and anode layer

58

respectively at potentials V

L

and V

H

, a suitable potential difference is applied to a selected one of electron-emissive regions

46

to cause that region

46

to emit electrons. As anode layer

58

attracts the emitted electrons towards faceplate structure

42

, focus coating

54

focuses the electrons towards the corresponding one of light-emissive regions

56

. The face electrodes, such as segmented electrodes

66

, control the electron trajectories in the manner described above. When the electrons reach faceplate structure

42

, they pass through anode layer

58

and strike corresponding light-emissive region

56

, causing it to emit light visible on the exterior surface of structure

42

. Other light-emissive elements

56

are selectively activated in the same way.

Directional terms such at “upper” and “top” 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. In as much 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 main portions of the spacers 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 as a circle, an oval, or a rectangle. As viewed along the length of a main spacer portion consisting of a combination of walls, the spacer portion can be shaped as a “T”, an “H”, or a cross. In these variations, each laterally segmented face electrode formed on a main spacer portion may extend fully or partially around, e.g., halfway or more around but not all the way around, the main spacer portion depending on factors such as the extent to which the segment potentials penetrate laterally through the main spacer portion.

Segmented face electrodes

66

can form parts of spacers configured similar to spacers

44

for causing electrons emitted from nearby electron-emissive regions in a flat-panel CRT display to be deflected toward the spacers in situations where undesired electron deflections away from the spacers are caused by mechanisms other than the backplate-side and faceplate-side electrical ends of the spacers being respectively located above the electrical ends of the backplate and faceplate structures. With each face electrode

66

still typically being closer to the faceplate structure than the backplate structure, the compensatory electron deflections toward the nearest spacers are produced according to the principles described above for face electrodes,

66

. In this regard, two or more laterally segmented face electrodes, such as face electrodes

110

,

112

, and

114

, may be substituted for each face electrode

66

.

On the other hand, as in the above-mentioned variation to the display of

FIGS. 7 and 8

, laterally segmented face electrodes generally akin to face electrodes

66

can be employed to cause electrons emitted by electron-emissive regions in a spacer-containing flat-panel CRT display to be deflected away from the nearest spacers when other mechanisms cause undesired electron deflections toward the spacers. The undesired deflections away from the nearest spacers can arise for various reasons such as the backplate-side electrical ends of the spacers being located below the electrical end of the backplate structure. In this case, the segmented face electrodes are typically located less than approximately one fourth of the distance from the backplate structure to faceplate structure. The compensatory electron deflections toward the nearest spacers are produced according to the reverse of the principles applied to face electrodes

66

. Each such segmented electrode can be replaced with two or more laterally segmented face electrodes.

Other mechanisms for controlling the potential field along spacers

44

may be used in conjunction with segmented face electrodes

66

. Electron deflections that occur due to thermal energy (heat) flowing through spacers

44

can be reduced to a very low level by applying the design principles described in Spindt, U.S. patent application Ser. No. 09/032,508, filed Feb. 27, 1998, now U.S. Pat. No. 5,990,614. Externally generated potentials may, in some instances, be applied to certain or all of electrode segments

66

1

-

66

N

. In other instances, face electrodes that contact end electrodes

62

or/and end electrodes

64

may be provided on main spacer portions

60

.

Conversely, end electrodes

62

or/and end electrodes

64

may sometimes be deleted. In such cases, each face electrode

66

is still spaced apart from the physical ends of its main spacer portion

60

, and thus from plate structures

40

and

42

. The same applies to face electrodes

110

,

112

, and

114

.

Field emission includes,the phenomenon generally termed surface emission backplate structure

40

in the present flat-panel CRT display can be replaced with an electron-emitting backplate structure that operates according to thermionic emission or photoemission. While control electrodes are typically used to selectively extract electrons from the electron-emissive elements, the backplate structure 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.

Number	Name	Date	Kind
4174523	Marlowe et al.	Nov 1979	A
4757230	Washington et al.	Jul 1988	A
4769575	Murata et al.	Sep 1988	A
4900981	Yamazaki et al.	Feb 1990	A
4923421	Brodie et al.	May 1990	A
5083058	Nonomura	Jan 1992	A
5130614	Staelin	Jul 1992	A
5227691	Marai et al.	Jul 1993	A
5229691	Shichao et al.	Jul 1993	A
5528103	Spindt et al.	Jun 1996	A
5532548	Spindt et al.	Jul 1996	A
5543683	Haven et al.	Aug 1996	A
5578899	Haven et al.	Nov 1996	A
5589731	Fahlen et al.	Dec 1996	A
5598056	Jin et al.	Jan 1997	A
5614781	Spindt	Mar 1997	A
5650690	Haven	Jul 1997	A
5675212	Schmid et al.	Oct 1997	A
5872424	Spindt et al.	Feb 1999	A

Number	Date	Country
0 405 262	Jan 1991	EP
0 580 244	Jan 1994	EP
WO 9900818	Jan 1999	WO

Fabrication of flat-panel display having spacer with laterally segmented face electrode

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Date Filed

Date Issued

Inventors

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Agents

CPC

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Abstract

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CROSS-REFERENCE TO RELATED APPLICATION

US Referenced Citations (19)

Foreign Referenced Citations (3)

Non-Patent Literature Citations (1)