Protected substrate structure for a field emission dispaly device

Abstract

A protected faceplate structure of a field emission display device is disclosed in one embodiment. Specifically, in one embodiment, the present invention recites a faceplate of a field emission display device wherein the faceplate of the field emission display device is adapted to have phosphor containing wells disposed above one side thereof. The present embodiment is further comprised of a barrier layer which is disposed over the one side of said faceplate which is adapted to have phosphor containing wells disposed thereabove. The barrier layer of the present embodiment is adapted to prevent degradation of the faceplate. Specifically, the barrier layer of the present embodiment is adapted to prevent degradation of the faceplate due to electron bombardment by electrons directed towards the phosphor containing wells.

Description

CROSS REFERENCE TO RELATED APPLICATION [0001] This Application is a Continuation-in-Part of co-pending, commonly-owned U.S. patent application Ser. No. 09 / 087,785, filed May 29, 1998, by Learn et al., and entitled “ENCAPSULATED FLAT PANEL DISPLAY COMPONENTS”.FIELD OF THE INVENTION [0002] The present claimed invention relates to the field of flat panel displays. More particularly, the present claimed invention relates to the “black matrix” of a flat panel display screen structure. BACKGROUND ART [0003] Sub-pixel regions on the faceplate of a flat panel display are typically separated by an opaque mesh-like structure commonly referred to as a matrix or “black matrix”. By separating sub-pixel regions, the black matrix prevents electrons directed at one sub-pixel from being overlapping another sub-pixel. In so doing, a conventional black matrix helps maintain color purity in a flat panel display. In addition, the black matrix is also used as a base on which to locate structures such as,...

AI Technical Summary

Benefits of technology

The barrier layer effectively confines contaminants, prevents vacuum degradation, and reduces electron-induced damage, enhancing the longevity of field emitters and maintaining display brightness and electrical robustness.

Problems solved by technology

Unfortunately, conventional polyimide matrices and the constituents thereof do not always remain confined within the polyimide material.

As a result, the vacuum environment of the flat panel display is compromised.

This polymerization, in turn, results in the formation of a dark coating on the faceplate.

The dark coating reduces brightness of the display thereby degrading overall performance of the flat panel display.

In addition to thermally induced contamination, conventional polyimide matrices also suffer from electron stimulated desorption of contaminants.

However, some of these emitted electrons will eventually strike the matrix.

This electron bombardment of the conventional polyimide matrix results in electron-stimulated desorption of contaminants (i.e. constituents or decomposition products of the polyimide matrix).

These emitted contaminants arising from the polyimide matrix are then deleteriously introduced into the vacuum environment of the flat panel display.

The contaminants emitted into the vacuum environment degrade the vacuum, can induce sputtering, and may also coat the surface of the field emitters.

Furthermore, conventional polyimide matrices also suffer from X-ray stimulated desorption of contaminants.

Such X-ray bombardment of the conventional polyimide matrix results in X-ray stimulated desorption of contaminants (i.e. constituents or decomposition products of the polyimide matrix).

As described above, these emitted contaminants arising from the polyimide matrix are then deleteriously introduced into the vacuum environment of the flat panel display.

Like electron stimulated contaminants, these constituents degrade the vacuum, can induce sputtering, and may also coat the surface of the field emitters.

Unfortunately, conventional polyimide matrices are not conductive.

Unfortunately, a conventional faceplate is subject to degradation when bombarded by electrons which ultimately impinge the faceplate.

The breakage of the chemical bonds then causes the faceplate to be light absorbing and, hence, is deleterious to the operation of the field emission display device.

As yet another drawback, electron bombardment of the faceplate may also cause conventional faceplates to outgas constituents thereof.

However, electron bombardment of such inexpensive high-sodium glass causes unwanted migration of contaminants (e.g. sodium) from the faceplate into the active region of the field emission display device.

Such migration of contaminants can result in harmful contamination of sensitive device elements (e.g. field emitters).

However, electron bombardment of such inexpensive high-sodium glass causes unwanted migration of contaminants (e.g. sodium) from the cathode substrate structure into the active region of the field emission display device.

Such migration of contaminants can result in harmful contamination of sensitive device elements (e.g. field emitters).

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