This invention relates generally to field emission electron sources and more particularly to field emission elements formed from a silicon-based semiconductor material and a method for forming the field emission elements.
In the technology of field emission devices and structures, an electric potential applied to or near a pointed surface of an emission element or emitter (or a plurality of such emission elements or emitters configured in an array) stimulates the emission of electrons from the pointed surface. A shape of the emitting surface, e.g. a pointed emitter tip, is selected to concentrate the electric field formed by the potential and thus maximize electron emissions into a vacuum surrounding the emitter. Increasing the electrical field intensity increases a current density of the emitted electrons, and the intensity is inversely further related to a radius of curvature of the emitting surface shape. Extremely pointed field emission tips are therefore desired.
In a field emission display, electrons emitted from the emission element are accelerated in a vacuum to impinge a phosphor screen that glows when struck by the electron. By contrast, in a cathode ray tube display, the electrons are generated by thermal emission from a heated cathode surface. In the field emission display the electrons are emitted from a “cold” cathode surface.
As illustrated in
A shape of the emission elements 10 is selected to maximize electron emission, as sharper emission elements produce more electrons and thus a brighter image. As the number of emission elements supplying electrons to each display pixel increases, the display reliability also increases, as it is known that the electron emissions from an emission element can decrease with time.
A voltage Va (greater than the voltage Vg) applied between the cathode electrode 8 and an anode electrode 24 accelerates the electrons toward a phosphor screen 25 (or other electroluminescent display device). The phosphor screen 25 and the anode electrode 24 are supported by a transparent anode substrate 26. Responsive to the impinging electrons, phosphor pixels comprising the phosphor screen 25 emit light observable from a surface 30 of the anode substrate 26. Typically, a plurality of emission elements 10 supply impinging electrons for a single pixel, wherein the plurality of emission elements 10 are insulated from other pluralities of emission elements 10, such that each plurality is independently controllable for emitting electrons that strike a single pixel.
For producing a color image, each pixel comprises a color pixel triad, further comprising a red sub-pixel, a green sub-pixel and a blue sub-pixel. The emission elements 10 associated with a pixel are segregated into a matrix of insulated addressable arrays, such that a first array is associated with the red sub-pixel, a second array is associated with the green sub-pixel and a third array is associated with the blue sub-pixel. To produce a blue color on the display, for example, the third emitter group is activated to emit electrons that impinge on the blue sub-pixel.
To permit operation at relatively low operating voltages, the emission elements 10 are typically constructed from a material exhibiting a low work function (such as molybdenum, where the work function is a measure of the amount of energy required for an electron to escape from the metal into the surrounding vacuum) to increase the electron emissions and shaped in the form of points 34. As can be seen from
Application of the voltage Vg between the gate electrode 16 and the cathode electrode 8 controls emission of electrons from the emission elements 10. As can be seen in
Opening/element alignment and opening size have been difficult to control in the prior art due to the extremely small geometries and tolerances associated with the openings 11 and the emission elements 10. Typically, to obtain opening/element alignment it has been necessary to employ a difficult and time-consuming masking step to form the openings 11, but slight errors in either the mask or the mask alignment relative to the substrate 14 can detrimentally affect the opening/element alignment and thus the emission of electrons. The difficulties encountered in fabricating such arrays increase significantly as the dimensions of the emitter emission elements 10 are reduced to a sub-micrometer or nanometer scale.
In addition to opening/element alignment concerns, according to the prior art the emission elements 10 are fabricated using known photolithographic masking, patterning and etching steps. This process limits element density and element quality. In particular, the density is limited by resolution of the photolithographic process. Also, since the emission elements are tapered, each occupies a larger area at a bottom surface than at a tip apex. Thus the required tapered base limits the emission element density, which lowers the image brightness. A higher element density is therefore desired to achieve a higher image brightness.
In an effort to overcome the disadvantages associated with the use of the photolithographic process for forming emitter emission elements, current research efforts form the emission elements 10 by directing a laser beam toward a substrate surface. When the laser beam strikes the surface material is removed therefrom, with the material remaining forming the emission elements 10. This process requires a laser scan over the entire substrate and thus can be time consuming. Disadvantageously, the emission elements 10 produced by the laser technique may not be uniform throughout the substrate.
Etching techniques to remove material layers from a silicon substrate are commonly used in semiconductor fabrication processes. Various dry and wet etchants are available, with each etchant offering specific etching characteristics, including material selectivity, etch uniformity and edge profile control. Plasma etching is one form of dry etching that employs a gas and plasma energy to create a chemical reaction that etches the desired material layer.
A conventional plasma etching system comprises a chamber, a vacuum system, a gas supply and a power source. After loading a silicon wafer onto a pedestal in the chamber, the vacuum system reduces the pressure and a reactive gas is supplied to the chamber. An electrode in the chamber is energized by a radio frequency power source to energize the gas to a plasma state, producing ions, electrons and radicals. A radio frequency bias applied to the substrate develops an electric field proximate the substrate to attract ions of the reactive gas to the substrate. These ions and the radicals synergistically etch the substrate according to a pattern in a mask overlying the substrate.
Selection of a specific reactive gas is based on the material to be removed during the etch process. For example, for etching a silicon dioxide material layer, CF4 and oxygen are typically used. In the energized state, the CF4 is disassociated into highly reactive carbon and fluorine radicals, in addition to a number of ions. The radicals and ions interact with the substrate, where the fluorine attacks the silicon dioxide, converting the silicon dioxide to a volatile material that is removed from the chamber by the vacuum system. Typically, the plasma etch process is performed at a temperature between about 15 and 45° C., and at a pressure between about 5 and 100 mTorr, depending on the reactor type employed for the process.
One embodiment of the present invention comprises a method for fabricating field emission elements within a silicon substrate. The method comprises providing a plasma etching chamber, supplying oxygen to the chamber, supplying a silicon etchant to the chamber, controlling a ratio of the oxygen to the silicon etchant and etching silicon from the silicon substrate to form the emission elements in the substrate, wherein an upper surface of the emission elements exhibits a generally convergent shape.
According to another embodiment the invention comprises a field emission display further comprising: an anode, a doped silicon substrate, emission elements randomly disposed on a surface of the silicon substrate and having a convergent tip region in a direction of the anode, an insulating layer overlying the substrate, wherein the tip region of each emission element is below an upper surface of the insulating layer and a gate overlying the insulating layer, wherein openings disposed through the insulating layer and the gate expose the tip region of certain ones of the emission elements, and wherein in regions of the substrate absent openings the tip region of other ones of the emission elements remain covered by the insulating layer.
The foregoing and other features of the invention will be apparent from the following more particular description of the invention, as illustrated in the accompanying drawings, in which like reference characters refer to the same parts throughout the different figures. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention.
Before describing in detail the particular method and apparatus for forming field emission elements according to the present invention, it should be observed that the present invention resides primarily in a novel and non-obvious combination of elements and process steps. So as not to obscure the disclosure with details that will be readily apparent to those skilled in the art, certain conventional elements and steps have been presented with lesser detail, while the drawings and the specification describe other elements and steps pertinent to understanding the invention in greater detail.
A method for forming emission elements 10 according to the present invention begins as illustrated in
A photoresist layer is deposited overlying the silicon nitride layer 54 and patterned according to known techniques to form a patterned photoresist layer 56. The pattern in the photoresist layer 56 is determined by a desired pattern for the field emission elements 10.
Using the pattern of the photoresist layer 56, the underlying silicon nitride layer 54 is etched according to known techniques (for example, using a CF4 chemistry) to form silicon nitride regions 54A (see
According to the present invention, the emission elements 10 are formed in the silicon layer 52 using a plasma etch process without the use of a photolithographic mask, thus reducing emission element fabrication costs. In addition, the present invention provides higher density and higher aspect ratio emission elements than the prior art techniques, resulting in better element uniformity and a brighter display image. During the plasma etch process, oxygen (O2) and sulfur hexafluoride (SF6) are supplied to the etching chamber in a ratio of oxygen to sulfur hexafluoride of about 1.5:1. Preferred flow rates are about 30 sccm for the oxygen and about 20 sccm for the sulfur hexafluoride. Hydrogen bromine (HBr) is also supplied to the etch chamber at a flow rate of about 50 sccm. In another embodiment, a chlorine-based compound (or other compounds including an element from Column VIIA of the periodic table) can be used in lieu of the hydrogen bromine and/or the sulfur hexafluoride.
During the etch process, a chamber pressure is maintained at about 30 mTorr. A radio frequency current generating about 60 W of power biases the substrate 50. A radio frequency source supplies about 1500 W to the plasma-forming electrode in the chamber.
The stated etch parameters are merely exemplary. Those skilled in the art recognize that variations of up to at least 20% from the stated parameters may produce desired results, i.e., formation of the emission elements 10. Further, the etch parameters may vary due to the design of the etching tool and the conditions of the chamber.
During the etch process, oxygen radicals combine with silicon on the upper surface 53 to form silicon dioxide regions 55, also referred to as micro-masks. These silicon dioxide regions 55 are not easily etched due to the material selective nature of the etchants employed, i.e., a higher etch selectivity to silicon than to silicon dioxide. Thus the emission elements 10 are formed as regions of the silicon layer 52 adjacent the silicon dioxide regions 55 are etched, while silicon regions masked by the silicon dioxide regions 55 remain substantially intact (i.e., are etched at a much slower rate).
This phenomenon of forming the silicon dioxide regions 55 and etching regions of the silicon layer 52 that are not masked by the silicon dioxide regions 55 is referred to as micro-masking. The process occurs when the etch chemistry is such that both etching (of the silicon) and deposition (of silicon dioxide to form the silicon dioxide micro-masks) occur simultaneously at a ratio of the rate of deposition to the rate of etching determined by the reactants employed during the process.
Both the SF6 gas and the HBr gas, in an embodiment in which it is present, participate in the silicon etching process. The SF6 etches faster but is less selective to the silicon dioxide and more isotropic (i.e., the resulting etch profile lacks the perpendicularity of a substantially anisotropic etch). The combination of the fluorine and the silicon form volatile SF4 that is removed from the etch chamber. The HBr gas is more selective to the silicon dioxide and etches very anisotropically, because the bromine is less reactive than fluorine and requires a greater ion bombardment energy to form volatile SiBr4.
The ratio of SF6 to HBr determines the degree of selectivity to the silicon dioxide and the anisotropic features of the resulting etch. Some of the oxygen ions and radicals combine with the silicon to form the silicon dioxide regions 55, since silicon dioxide is not a volatile material.
The ions and radicals that etch the substrate 50 are derived from both the SF6 and the HBr (in an embodiment where it is present). The ions strike the surface of the silicon layer 52 substantially normally or anisotropically because they are attracted by the negative potential applied to the substrate 50. Further, since the ions strike the surface at about 90 degrees to the surface, they tend to drive the etch process vertically, rather than laterally, resulting in a predominantly vertical etch process, creating the emission elements 10 with a higher density than the prior art processes. The free radicals, which carry no charge, strike the silicon layer 52 from substantially all directions because they are not attracted to the substrate 50. Instead the motion of the radicals is influenced by collisions with other atoms in the chamber and therefore is essentially random in all directions. As the ions impinge the exposed silicon surface, they tend to accelerate the etch process that was begun by the radicals in the first several monolayers of the silicon layer 52.
As the etching process begins, the upper surface 53 of the silicon layer 52 comprises a relatively flat surface. As the silicon dioxide regions 55 are formed, the etch process removes material adjacent the silicon dioxide regions 55, forming substantially rectangular vertical structures 10A as illustrated in the close-up view of
Beginning in
A chemical/mechanical polishing step (CMP) is performed to planarize an upper surface 64 of the substrate 50. See
As illustrated in
As illustrated in
Using the opening 88 as a pattern, an opening 89 is formed in the aluminum layer 82, using a chlorine-based etch chemistry, for example. Through the opening 89, an opening 90 is formed in the material layer 80 and the silicon dioxide layer 66. As can be seen in
After formation of the opening 90 the photoresist layer 84 is removed. Note that a plurality of emission elements 10 are formed within each opening 90, although only a single emission element 10 is illustrated in
A physical deposition process (according to one embodiment) deposits a material layer 96 over the tip 10A through the opening 90, and deposits a conductive layer 98 over the aluminum layer 82. See
As shown in
As illustrated in
A top view of the completed structure is illustrated in
A red sub-pixel array 120 comprises a plurality of emission elements 10 that when energized emit electrons that strike a red sub-pixel for producing a red color on the phosphor screen 25. Similarly, electrons emitted from a blue sub-pixel array 122, comprising a plurality of emission elements 10, impinge a blue sub-pixel to produce a blue color and electrons emitted from a green sub-pixel array 124, comprising a plurality of emission elements 10, impinge a green sub-pixel to produce a green color. As illustrated in
An architecture and process have been described as useful for forming field emission elements in a semiconductor substrate. Specific applications and exemplary embodiments of the invention have been illustrated and discussed, which provide a basis for practicing the invention in a variety of ways and in a variety of circuit structures. Numerous variations are possible within the scope of the invention. Features and elements associated with one or more of the described embodiments are not to be construed as required elements for all embodiments. The invention is limited only by the claims that follow.
This present application is a continuation of U.S. patent application Ser. No. 11/057,690, entitled “HIGH-DENSITY FIELD EMISSION ELEMENTS AND A METHOD FOR FORMING SAID EMISSION ELEMENTS” filed on Feb. 14, 2005, by Seong Jin Koh, et al., U.S. Pat. No. 7,564,178. The above-mentioned application is commonly assigned with the present application and incorporated herein by reference in its entirety.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 11057690 | Feb 2005 | US |
Child | 12506090 | US |