05/419827

10/14/1975

11/28/1973

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The United States of America as represented by the Secretary of the Army (Washington, DC)

345/80

345/211, 348/E03.016, 348/800

G09F13/22; G09G3/30; H01L21/00; H01L27/00; H04N3/14; G06F3/14

340/324A,324AD,166EL,168SR 357/2,24

Curtis, Marshall M.

Harwell, Max Edelberg Nathan Gibson Robert L. P.

I claim

1. An electroluminescent display panel comprising:

2. An electroluminescent display panel as set forth in claim 1 wherein said light translucent substrate is glass.

3. An electroluminescent display panel as set forth in claim 1 wherein said transparent electrically conductive layer is tin oxide.

4. An electroluminescent display panel as set forth in claim 1 wherein said layer of vitreous material is germanium.

5. An electroluminescent display panel as set forth in claim 1 wherein said layer of vitreous material is sulfur.

6. An electroluminescent display panel as set forth in claim 1 wherein said layer of vitreous material is selenium silicon oxide.

7. An electroluminescent display panel as set forth in claim 1 wherein said layer of vitreous material is aluminum oxide.

BACKGROUND AND SUMMARY OF THE INVENTION

This invention is in the field of large flat panel electroluminescent diode read-out displays using amorphous semiconductors with vitreous material for switching video signals across electroluminescent elements.

Previously, the development of display panels was directed toward gas discharge elements, solid breakdown voltage devices, etc. which were triggered by alternating current (a.c.) voltage. More recently, display panels using miniaturized electroluminescent elements for transmittal of light are used wherein the elements are turned "on" by a d.c. voltage.

The present invention comprises a predictable and efficient breakdown amorphous semiconductor having a vitreous switching layer that switches "on" by coincident voltages at the rear and front metal islands on each side thereof. These coincident voltages are produced as horizontal and vertical clock pulses at the output of shift registers. A positive d.c. voltage source is applied to the rear electrode on the vitreous switching layer and sets up an electric field in the vitreous and electroluminescent layers between the positively charged rear electrode and a grounded electrically conductive layer, which is contiguous with the electroluminescent layer and the glass substrate. When output clock pulses from both shift registers are coincident at their respective islands in any one element, the vitreous switching layer will break down in the area between the metal islands and start conducting current therethrough if a video signal is also present. The electric field provided by the d.c. voltage source applied to the rear electrodes will sustain conduction in the vitreous and electroluminescent layers, thus holding the electroluminescent layer in a luminescent condition even after the video signal is removed, and can only be stopped by removal of the d.c. voltage source. For the panel to accept a subsequent display, the d.c. voltage source is simply switched off for removal of the alpha-numeric display and switched back on again to establish the electric field for the subsequent display.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic circuit showing bucket-brigade type scanners, feeding rows and columns of the amorphous semiconductor electroluminescent elements;

FIG. 2 is a diagrammatic illustration of a single element amorphous semiconductor electroluminescent element; and

FIG. 3 is a V-I curve of the electrical characteristics of the vitreous switching element within the amorphous semiconductor.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1 illustrates a partial schematic of a multi-element electroluminescent display panel. A typical element 10 (shown in the upper right) is biased by d.c. voltage source 12 when switch SW1 is closed, thus placing an electric field across element 10. Element 10 is addressed by clock pulses from column and row bucket brigade shift registers, respectively, arriving on column Y and row X. The column bucket brigade shift register is comprised of horizontal clocks A and B, represented by numerals 6 and 8, and horizontal synchronizing pulse generating circuit 20. The row bucket brigade shift register is comprised of vertical clock 22 and vertical synchronizing pulse generating circuit 21. Horizontal clocks 6 and 8 produce square waves 6a and 8a that are 180° out of phase with each other. Square waves 6a and 8a are applied to alternate gates of column shift register MOSs to "hand off", in a bucket brigade manner, the horizontal synchronizing pulses from circuit 20 along the column shift register MOSs Q10, Q12, Q14, Q16, Q18, and others (not shown). The outputs from the column shift register MOSs are applied to the gates of video MOSs Q20, Q22, Q24, Q26, and others (not shown) totalling the number of columns in the matrix. Video signals are applied to terminal 28. Terminal 28 is connected to all of the source terminals of the video gate MOSs Q20, Q22, Q24, Q26, etc. When a video signal is present at terminal 28 and the video MOSs are gated on by display information from horizontal clocks 6 and 8, the video signal will be transmitted to islands 24a of elements 10. This display information present at clocks 6 and 8 may be transmitted on a high frequency carrier wave, such as a laser beam or a VHF channel, into the horizontal clocks of the column bucket brigade shift register. Similarly, display information present at vertical clock 22 "hands off" the vertical signal pulses from circuit 21 along row shift register MOSs Q40, . . . , Q28, and others (not shown) totalling the number of rows in the matrix. This display information is first received, amplified, and decoded using circuitry similar to a television receiver (with such circuitry not being a part of this invention) and is produced as digitalized information at the output of the column and row shift registers. The shift registers operate similar to deflected coils of a television, while the video gate MOSs operate as modulation devices. When there is coincidence of the digitalized information, the video signal addresses an electroluminescent element 18. The horizontal shift register operator typically at 5 kilocycles for an element 18 addressing time of 200 microseconds.

Referring to FIG. 2, a typical display element 10 of this invention is shown. Element 10 is an amorphous semiconductor that comprises a vitreous switching element layer 26, an electroluminescent element 18 made of layered p-n material, an electrically conductive layer 16, and a glass substrate 32. Rear electrode 14 and rear metal islands 14a are vapor deposited on the rear side of layer 26. Front electrode 24 and front metal island 24a are vapor deposited on the front side of layer 26. An external d.c. voltage source 12 is connected to rear electrode 14 when switch SW1 is closed. Layer 16 is connected to ground terminal 30. Electrical leads from a column and a row, represented as column Y and row X, are shown connected to front metal island 24a and rear metal island 14a, respectively. Islands 14a and 24a are positioned directly opposite each other on layer 26. Also, rear electrode 14 and front electrode 24 are positioned directly opposite each other on layer 26. Operation of the amorphous semiconductor will be explained in more detail later with reference to FIG. 2.

The display panel is prepared by the process as explained hereinbelow. Starting with glass substrate 32, an electrically conductive layer 16 of transparent material, such as tin oxide, is evaporated on one side thereof. A direct current electroluminescent layer 18 is then vapor deposited on conductive layer 16. Layer 18 may be a polycrystalline heterjunction sandwich structure made of group II-VI materials, or alternately a layer composed of many single crystalline light emitting diodes. In either case, layer 18 will become operative at a few volts and milliamperes of d.c. power, e.g., 8 volts at 1 milliamperes. Typically, an embodiment of a panel made in this manner has 250,000 elements in a panel having 500 rows and 500 columns. If layer 18 is polycrystalline heterjunction sandwich structure, metallized square electrodes 24 and small metal islands 24a enclosed by and insulated from electrodes 24 are vapor deposited through a photoetched mask onto the back side of electroluminescent layer 18. In further developing element 10 for use as a display element, electrodes 24 and islands 24a are separated by an insulator material, which is deposited by photoresist techniques, such that electrodes 24, but not front islands 24a, are insulated from column leads. The insulator material may be aluminum oxide. These column leads are deposited over the insulator material and are connected to each of the front islands such that the column leads are insulated from front electrode 24. However, the remainder of front electrode 24 not insulated from the column lead is in intimate contact with layer 18. The column leads are connected at their opposite end to the drain terminal of the various video MOSs Q20, Q22, Q24, Q26, etc. Vitreous switching layer 26 is deposited over the electroluminescent layer 18, the insulator material layer, and the column leads deposited thereon. Layer 26 is from 1 to 10 microns in thickness. Layer 26 may be vacuum deposited, rf sputtered, etc. A great variety of materials are known to exhibit the switching effect needed for layer 26. Some of these materials are germanium, sulfur, selenium silicon oxide, aluminum oxide, etc. On top of this vitreous material layer 26 are deposited the rear electrodes and rear islands in the same manner that the front electrodes and front metal islands were deposited on layer 18, .e., by vapor depositing through a photoetched mask. The electrodes and islands deposited on each side of layer 26 are in exact registration. A layer of insulator material is deposited by photoresist techniques such that the rear electrodes 14, but not the rear metal islands 14a, are insulated from row leads. The row leads are connected to the rear metal islands. Rear electrode 14 is in intimate contact with layer 26. Lead wires from all of the rear electrodes 24 are connected to power supply 12. The row leads are connected to the rear metal islands at one end and to the bucket brigade vertical shift register MOSs Q28, Q30, Q32, Q34, Q36, Q38, Q40, etc., at the other end. With pulses on row leads from the bucket brigade vertical shift register MOSs and pulses on the bucket brigade horizontal shift register MOSs connected, respectively, to rear metal islands and front metal islands, the vitreous switching layer 26, which these islands are connected across, conducts through the area between the particular metal islands 14a and 24a being pulsed. The conducting area between islands 14a and 24a forms a generally cylindrical aisle through layer 26. The cylindrical aisles extending through the electroluminescent layer may simply be the electroluminescent layer 18 left uncovered, or grooves etched all the way through to conductive layer 16. These grooves are needed for optical separation such that light from one element cannot be scattered into the next element. The grooves may also be filled with black resin by simply rubbing the resin therein. A typical I-V characteristic curve for the vitreous material of layer 26 is shown in FIG. 3. These characteristics are discussed below with reference to the voltages existing between electrodes 14 and 24.

FIG. 1 illustrates a partial schematic of the overall scanning system with the matrix of amorphous semiconductor attached to voltage source 12 and to the various column and row leads. When switch SW1 is closed, the positive terminal of voltage source 12 is connected to rear electrodes 14 on all the semiconductors, establishing a potential gradient through all of the elements between rear electrode 14 and layer 16 that is connected to ground 30. Front electrode 24 is, therefore, at some floating potential between the positive voltage from voltage source 12 and the ground potential on layer 16. The voltage differential between electrodes 14 and 24 is close to, but under, the amount needed to initiate conduction through the area of the vitreous switching layer 26 that is between rear electrode 14 and front electrode 24. When layer 26 conducts there is also conduction through layer 18 between front electrode 24 and layer 16, thus causing electroluminescent layer 18 to luminesce. Scanner voltages from horizontal clocks A and B, represented by pulses 6a and 8a, respectively, apply positive pulses to the gate electrodes of alternate horizontal shift register MOSs Q10, Q12, Q14, Q16, Q18, etc., and others (not shown). The horizontal shift register MOSs alternally gated "on", the horizontal synchronizing pulse from circuit 20 is passed along the horizontal shift register MOSs in bucket brigade "hand off" fashion. These "hand off" horizontal synch pulses are applied to the gates of video MOSs Q26, Q24, Q22, Q20, and others (not shown). When pulse 6a from clock 6 is positive, pulse 8a from clock 8 is negative, and vice versa. Video information, applied at terminal 28 is connected to the source terminals of the video MOSs. Electrical leads from the drain terminals of the video MOSs are connected to column leads which are, in turn, connected to metal islands 24a of the semiconductors. In operation, a horizontal synchronizing pulse circuit, represented by block 20, produces synchronous pulses that are "moved along" the bucket brigade horizontal shift register MOSs Q10, Q12, Q14, Q16, and Q18 by alternate pulses 6a and 8a. Vertical clock 22 applies positive voltage pulses to alternate gates of the bucket brigade vertical shift register MOSs Q28, Q30, Q32, Q34, Q36, Q38, and Q40. A vertical synchronizing pulse produced, through resistor R5, at the output of vertical synchronizing pulse circuit 21 is also "moved along" the bucket brigade vertical shift register MOSs. More specifically, video information is stored in one of the two storage registers, or horizontal clocks A and B, represented by blocks 6 and 8, while the vertical shift register 22 discharges its previously stored information into all elements of one column simultaneously. Storage and discharge of the registers are out of phase with each other as shown by the output waves 6a and 8a therefrom in FIG. 1. The video input signals to the matrix at terminal 28 is the actual source of information that is displayed on the various electroluminescent elements of the matrix. The bucket brigade vertical shift register MOSs gate the various video MOSs "on" such that when the video information is present at the source terminal of the video MOSs the information is passed to the drain terminal and on to the islands 24a of the elements.

In the shift register addressing method, the column scanner is a slow shift register that scans, say for example, the right column. During the time that the slow register scans this one column, the fast register scans all of the rows in a sequential manner. Therefore, while the extreme right column has a voltage applied to the middle metal islands 24a, all of the vertical synchronizing pulses from 21 are applied to the rear metal islands 14a. Only at the addressing coincidence of the column Y and row X elements 10 along this extreme right column will the video signal, present at terminal 28 and at the source terminal of the video MOSs, switch the vitreous layer 26 "on", causing luminescence of that element. Instantaneously, only the element 10 in the extreme upper right has the full voltage applied across the rear metallic island 14a and the middle metallic island 24a. If the video signal is present at the video input terminal 28, this signal switches the element which has the voltages coincidence thereacross and the element -- in this case element 10 -- will luminesce. The slow column scanner will then switch to the next column and the fast scanner will switch on all the rows sequentially before the slow column scanner switches again. The video signal has a larger voltage peak than the column and row scanner voltages, and consequentially switches the coincidence address elements "on". After the entire panel has been scanned, the scanners may be switched off and the image retained. The image may be erased by opening switch SW1 to the external d.c. voltage source 12. The panel may then be readdressed. An important alternative to erasing the image over the entire panel is that of erasing one line at a time by inserting a switch in each line (row and column) and selectively opening these switches after the entire panel has been scanned. Also, selective erasure of single lines of the alpha-numeric read out on the panel may be controlled from the broadcasting station by coded signals to which the receiver is sensitive.

In operation, assume that the extreme right column is pulsed, the strongly positive pulse video signal, at the source terminal of video MOS Q26, is passed through MOS Q26 to front metal island 24a of element 10. The video signal sets up a high electric field in the small area between the rear metal island 14a and front metal island 24a. The video signal voltage is greater than the threshold voltage that has been established across layer 26 by applying d.c. voltage source 12 to rear electrode 14. Therefore, when the video signal is applied the small area of layer 26 that is between islands 14a and 24a will break-down and begin conducting. The differential voltage between the positive d.c. voltage applied to electrode 14 and the floating voltage on electrode 24 is sufficient to break-down the entire area of layer 26 when the area between islands 14a and 24a has broke-down. Conduction is sustained through layer 26 by d.c. voltage source 12 even after the video signal has been removed. That is, the unswitched vitreous material of layer 26 has high impedance until the video signal is applied and the low impedance after the video signal is applied. After the column and row shift registers have scanned the entire panel, the alpha-numeric read-out will remain on the display panel until the panel is readdressed. When conduction begins through layer 26 this conduction extends through layer 18 and into layer 16. The electroluminescent material in layer 18 will luminesce when conduction is taking place therein.