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A process for anodically bonding an array of spacer columns to one of the inner major faces on one of the generally planar plates of an evacuated, flat panel video display. The process includes using a generally planar plate having a plurality of spacer column attachment sites; providing electrical

A process for anodically bonding an array of spacer columns to one of the inner major faces on one of the generally planar plates of an evacuated, flat panel video display. The process includes using a generally planar plate having a plurality of spacer column attachment sites; providing electrical interconnection between all attachment sites; coating each attachment site with a patch of oxidizable material; providing an array of unattached permanent glass spacer columns, each unattached permanent spacer column being of uniform length and being positioned longitudinally perpendicular to a single plane, with the plane intersecting the midpoint of each unattached spacer column; positioning the array such that an end of one permanent spacer column is in contact with the oxidizable material patch at each attachment site; and anodically bonding the contacting end of each permanent spacer column to the oxidizable material layer.

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What is claimed is: 1. A process for a flat panel display having a substrate having an attachment site for a spacer formed as a silicate glass element having a contacting surface having an oxidizable material thereon, the process comprising: positioning the silicate glass element on the contacting

What is claimed is: 1. A process for a flat panel display having a substrate having an attachment site for a spacer formed as a silicate glass element having a contacting surface having an oxidizable material thereon, the process comprising: positioning the silicate glass element on the contacting surface substantially located at the attachment site; and anodically bonding the contacting surface to the attachment site. 2. The process of claim 1, further comprising thermally cycling a face plate before positioning the spacer thereon. 3. A process for fabricating a flat panel display having a substrate having an attachment site comprising: providing at least one silicate glass element having a contacting surface having a volume of oxidizable material thereon; contacting the at least one silicate glass element having the volume of oxidizable material on the contacting surface thereof at the attachment site; heating the substrate and the at least one silicate glass element; establishing a potential between the attachment site and a noncontacting surface of the at least one silicate glass element, the attachment site being positively biased with respect to the noncontacting surface, the potential sufficient to cause oxygen ions to migrate from the at least one silicate glass element having the volume of oxidizable material thereon at the attachment site to cause a portion of the oxidizable material to oxidize to form an oxide interface for bonding a portion of the at least one substrate to the silicate glass element. 4. The process of claim 3, wherein the substrate and the at least one silicate glass element are heated to about a transition temperature of the at least one silicate glass element. 5. The process of claim 3, wherein the established potential falls within a range of about 500 to 1,000 volts. 6. A process for fabricating a flat panel display having a laminar silicate glass substrate comprising: covering at least a portion of the substrate with an anti-reflective layer; covering at least a portion of the anti-reflective layer with a light-absorbing layer; patterning the light-absorbing layer to form a generally opaque matrix to serve as a contrast mask during operation of the display, the opaque matrix exposing portions of the anti-reflective layer for depositing a luminescent phosphor material thereat; covering at least a portion of the opaque matrix and the exposed portions of the anti-reflective layer with a transparent conductive layer; depositing an oxidizable material layer over at least a portion of the transparent conductive layer; patterning the oxidizable material layer to form oxidizable material patches for spacer attachment sites by exposing portions of the underlying transparent conductive layer; providing a plurality of spacers, each spacer of the plurality of spacers having a bondable surface having a volume of oxidizable material thereon; contacting the bondable surface of the each spacer of the plurality of spacers with one of the spacer attachment sites; and anodically bonding the bondable surface of each spacer of the plurality of spacers to the one of the spacer attachment sites. 7. The process of claim 6, further comprising: depositing a protective sacrificial layer over the oxidizable material patches and over the exposed portions of the transparent conductive layer; and patterning the protective sacrificial layer to expose each of the oxidizable material patches. 8. The process of claim 7, wherein the protective sacrificial layer is selected from a group consisting of cobalt oxide and aluminum, chromium, cobalt, and molybdenum metals. 9. The process of claim 7, wherein the patterning of the protective sacrificial layer also leaves a channel surrounding the oxidizable material layer at the one of the spacer attachment sites, the channel exposing the underlying transparent conductive layer. 10. The process of claim 7, wherein the spacer attachment sites are electrically interconnected during the anodically bonding by the underlying transparent conductive layer. 11. The process of claim 7, wherein the anti-reflective layer has an optical thickness of about one-quarter wavelength of light in a middle of a visible spectrum Å. 12. The process of claim 7, wherein the light-absorbing layer comprises at least one of a colored transition metal oxide and cobalt oxide having a color in the range of dark blue to black. 13. The process of claim 7, wherein the transparent conductive layer comprises a material selected from a group consisting of indium tin oxide and tin oxide. 14. The process of claim 7, wherein the oxidizable material layer comprises a material selected from a group consisting of silicon and oxidizable metals. 15. The process of claim 7, wherein the spacer attachment sites are situated in regions of the opaque matrix. 16. The process of claim 7, wherein the providing the plurality of spacers includes: preparing a glass fiber bundle section having a set of permanent glass fibers, each of which is completely surrounded by filler glass that is selectively etchable with respect to the set of permanent glass fibers; sintering the glass fiber bundle section; drawing the glass fiber bundle section; forming a block by stacking the drawn glass fiber bundle section and sintering the stacked glass fiber bundle section; slicing the block to form a uniformly thick laminar slice having a pair of opposing major surfaces; and polishing both of the opposing major surfaces of the laminar slice to a final thickness which corresponds to a desired spacer length. 17. The process of claim 16, wherein for cylindrical solid spacers, each of the set of permanent glass fibers is clad with the filler glass, and each the filler glass clad permanent glass fiber is surrounded by six other identically clad fibers, seven of which together form a repeating, hexagonally packed unit through a cross-section of the glass fiber bundle section. 18. The process of claim 16, wherein for spacer support columns having a square cross-section, the set of permanent glass fibers is cubically packed as a repeating array through a cross-section of the glass fiber bundle section, with each of the set of permanent glass fibers surrounded by eight filler glass fibers having identical cross-sections. 19. A process for a flat panel display having a substrate having an attachment site for a spacer formed as a silicate glass element having contacting surface having an oxidizable material thereon located at the attachment site, the process comprising: anodically bonding the contacting surface to the attachment site. 20. The process of claim 19, further comprising thermally cycling a face plate before positioning the spacer thereon.