FR2902574A1 - Cathodic element for field emission display type image display panel, has control electrodes supplied with respective voltages and comprising conductor elements, where voltage of one electrode is less than voltage of another electrode - Google Patents

Abstract

The element (1`) has a set of cathodo-emissive studs (41-43) distributed in three rows (L`1-L`3) and electrically connected to a cathode electrode (3`). Two control electrodes (5, 6) comprise respective conductor elements (51, 52, 61, 62), in which the distance between the elements (51, 52) is greater than the distance between the elements (61, 62). The electrodes (5, 6) are supplied with respective voltages (V5`, V6), where the voltage (V5`) is less than the voltage (V6). The rows are intercalated between respective conductor elements (51, 52, 61, 62) of the control electrodes. An independent claim is also included for a method for displaying an image using a field emission display.

Description

With reference to FIG. 3 which relates to the prior art, the invention

  relates to a cathode element 1 comprising a cathode substrate 2, a cathode electrode 3, a plurality of cathodo-emissive pads 41, 42, 43 which are distributed in at least three lines L1, L2, L3 and which are electrically connected to the cathode electrode 3, and a control electrode 5 comprising conductive elements arranged so that each line L1, L2, L3 of cathodo-emissive pads 41, 42, 43 is interposed between two adjacent conductive elements of the electrode of control 5. Such cathode elements serve in particular, when associated with anode elements, to form cathodoluminescent transmitters; such cathodoluminescent transmitters, arranged in a row and column array, serve in particular to form field effect display panels (FED or Field Emission Display in English). The set of cathodic elements of the cathodoluminescent transmitters of each column then share the same cathode electrode (or the same control electrode), and all the cathodic elements of the cathodoluminescent transmitters of each line then share the same control electrode ( or, respectively, the same cathode electrode). A FED-type image display panel comprises an anodic front panel and a cathodic rear panel providing between them a cathode space generally under vacuum. The anodic front panel of an EDF generally comprises an anode substrate, a common anode electrode, and pads of cathodoluminescent materials; there is a cathodoluminescent pad in front of each cathode element. The cathode backplane of an EDF generally includes, superimposed in this order, a cathode substrate, a cathode electrode array, an electrical insulation layer, and an array of control electrodes. Each cathodoluminescent emitter is therefore a triode whose third electrode is the anode electrode. The cathode electrodes support cathode-emissive pads, formed for example of a group of micro-tips or carbon nanotubes; each cathode element therefore comprises a plurality of cathodo-emissive pads; each cathodo-emissive pad is exposed to the cathode space through an opening in the control electrode and in the electrical insulating layer; when, as illustrated in FIG. 3, the cathodo-emissive pads of each cathode element are distributed in several lines, this opening corresponds to one groove per line. The cathodo-emissive pads 41, 42, 43 are generally located in the central part of each groove. For the image display, an electric field is generated within each triode or cathodoluminescent transmitter, between the anode electrode and the cathode electrode, which allows the extraction of electrons from the plurality of cathodo-emissive pads of this transmitter; under the effect of the electron bombardment of the cathode-luminescent pad of this transmitter, the emitter emits light so as to display a pixel or a sub-pixel of the image to be displayed. A pixel is a picture element while a subpixel is a picture element in a specific primary color. FIG. 1 schematically represents a conventional cathodic element portion of the prior art, namely a cathodo-emissive pad 42 deposited on a cathode electrode 3 at the bottom of a groove made in the electrical insulation layer 7 and in a conductive element of a control electrode 5; in operation, by applying a control voltage V5 greater than the cathode voltage V3 (which for example, as in FIG. 1, is zero when the sub-pixel to which this cathode element belongs is lit), it has been found that the field generated electric within each cathodo-emissive pad 42 had a significant lateral component, which tends to diverge the electron beam F emitted by this pad, as shown in Figure 1, which causes a widening of the light spot generated on the anodic front panel; overall, this broadening of the light spots is detrimental to the quality of the image display by degrading the luminance and sometimes degrading the purity of the primary colors. A solution commonly used in the prior art to reduce the divergence of the electron beams is to reduce the dimensions of the cathodo-emissive pads; a disadvantage of this solution is that it requires the implementation of expensive manufacturing processes, such as high resolution lithography; another disadvantage is that it increases the potential difference V5 - V3 which is necessary to obtain a predetermined emission current. An object of the invention is to avoid, if not to limit, the aforementioned drawbacks. For this purpose, the subject of the invention is a cathode element comprising a cathode substrate, a cathode electrode, a plurality of cathode-emissive pads which are distributed in at least three lines and which are electrically connected to said cathode electrode, a first electrode control unit comprising conductive elements, and a second control electrode comprising other conductive elements, wherein each cathodo-emissive pad line is interposed between a conductive element of said first control electrode and a conductive element of said second control electrode. . Thanks to the structure of the cathode element according to the invention, it is thus possible to limit the angular divergence of the electron beam emitted by each cathodo-emissive pad without resorting to expensive manufacturing means, such as high-resolution lithography. Preferably, the distance between the adjacent lines of cathodo-emissive pads varies by at least a factor of 1.5. Preferably, the cathode element comprises an electrical insulation layer interposed between firstly said cathode electrode and secondly the first and the second control electrode. Preferably, the first and second control electrodes are coplanar. Thus, all the conductive elements of each control electrode can be advantageously etched in the same conductive layer. Preferably, each cathodo-emissive pad is based on carbon nanotubes. Preferably, said cathodo-emissive pads are electrically connected to said cathode electrode via an interposed resistive layer. In the event of a short-circuit of one or the other cathodo-emissive pad, it is thus avoided to neutralize all the cathodo-emissive pads of the cathode element. The invention also relates to an image display panel comprising an array of cathodoluminescent transmitters, wherein each cathodoluminescent transmitter is in accordance with the invention. Each cathodoluminescent emitter generally comprises an anode element comprising itself an anode substrate and an anode electrode coated with a cathodoluminescent layer, providing, with the cathode element with which it is associated, a cathode space; this cathode space formed between the two substrates is generally under vacuum. Preferably, all the cathode elements are carried by the same cathode substrate, and all the anode elements are carried by the same anode substrate.

  Preferably, said cathodoluminescent transmitters being distributed in rows and in column, the set of cathodic elements of the cathodoluminescent transmitters of each column share the same cathode electrode, and all the cathodic elements of the cathodoluminescent transmitters of each line share the same first and the same second control electrode. The subject of the invention is also an image display method using the panel according to the invention, in which, using a cathodoluminescent emitter of said panel, each pixel is displayed, and, where appropriate, each sub-pixel, of said image, wherein, for the display of each transmitter, the voltage V5 applied to the first control electrode is lower than the voltage V6 applied to the second control electrode of said transmitter. The voltage V5 can be negative; preferably, the voltage difference V6 - V5 is amplitude-adapted to reduce the angular divergence of the electron beams emitted by the cathodo-emissive pads. The reduction of beam divergence generally has the effect of substantially improving the quality of the display of the images, without implying significant additional costs in the manufacture of the panels. Preferably, the distance between the adjacent members of the first control electrode is greater than the distance between the adjacent members of the second control electrode. The invention will be better understood on reading the description which will follow, given by way of nonlimiting example, and with reference to the appended figures in which: FIG. 1, already described, schematically represents a cathode element portion; classical art of the prior art, in operation; - Figure 2 shows, in operation, a cathode element portion according to the embodiment of the invention of Figure 4; - Figure 3 already described, represents a conventional cathode element of the prior art; FIG. 4 represents an embodiment of a cathode element according to the invention. In order to simplify the description and to show the differences and advantages that the invention presents with respect to the prior art, identical references are used for the elements that provide the same functions. With reference to FIG. 4, the cathode element 1 'according to the invention comprises, in the order of successive deposits, on a cathode substrate 2, a cathode electrode 3', an electrical insulation layer 7, and substantially on the same plane, a first control electrode 5 'and a second control electrode 6; the first control electrode 5 'comprises a lateral conductive bus of potential distribution on which are connected, transversely to this bus, two conductive elements 51 and 52; the second control electrode 6 also comprises a lateral conductive bus of potential distribution on which are also connected, transversely to this bus, two conductive elements 61 and 62; each conductive element 51 of the first control electrode 5 'is interposed between two conductive elements 61, 62 of the second control electrode 6, or, failing this, each conductive element 62 of the second control electrode 6 is interposed between two elements conductors 51, 52 of the first control electrode 5 '; between each conductive element 51, 52 of the first control electrode 5 'and each adjacent conductive element 61, 62 of the second control electrode 6, trenches are made in the insulation layer up to the cathode electrode 3 , in which cathodo-emissive pads 41, 42, 43, here in carbon nanotubes, are formed in a manner known per se, which are thus divided into three lines L'1, L'2, L'3 and electrically connected to the cathode electrode 3.

  Finally, the distance between the adjacent lines L'1, L'2, L'3 of cathodoemissive pads differ by at least a factor 1.5; more precisely, the distance between the adjacent lines L'3 and L'2 is at least a factor 1.5 greater than the distance between the adjacent lines L'2 and L'1. The technical effect of this difference will be explained below. Thanks to the cathodo-emissive element structure that has just been described, it is possible to apply a different control potential on either side of each cathode-emitting stud line 41, 42, 43, which allows, by suitably choosing the potential difference between the two control electrodes, to limit the angular divergence of the electron beam emitted by each line. According to one variant, the cathode electrode is electrically connected to the pads, not directly as before, but via a resistive layer: for example, the trench previously described is continued in its center, through the cathode electrode, and is deposited. , in the central grooves thus created and overlapped on the edges of these grooves, resistive strips on which is then formed the cathodoemissive pads. According to another variant, which can be cumulated with the first, the edges of the electrodes are offset with respect to the edge of the trenches or grooves made in the insulation layer. In a manner known per se, an array of cathodic elements 1 'distributed in the same cathode substrate in rows and columns is formed; the successive layers are deposited on this substrate, forming trenches and cathodo-emissive pads; all the cathode elements of each column share the same cathode electrode, and all the cathode elements of the cathodoluminescent transmitters of each line share the same first and the same second control electrode; a cathodic rear panel is thus obtained. We can invert the rows and columns without departing from the invention. As in the prior art, an anodic front panel is manufactured and the two panels are assembled so as to provide a cathode space between them in which a vacuum is created. An EDF-type image display panel according to the invention is thus obtained, formed of an array of cathodoluminescent transmitters each comprising a cathode element according to the invention. To display an image using such an EDF panel, each pixel or sub-pixel of this image is displayed using a cathodoluminescent emitter of this panel; according to the invention, for the display of each transmitter, the voltage V5 applied to the first control electrode is lower than the voltage V6 applied to the second control electrode of said transmitter; the voltage difference V6 - V5 is adapted to reduce the divergence of the electron beams emitted by the cathodo-emissive pads; this voltage difference induces an inclination of the trajectories of the electrons as described below. According to the invention, therefore, at the level of each cathodo-emissive pad, an asymmetry of the electric field is created; FIG. 2 schematically represents a cathode element portion according to the invention, namely a cathodo-emissive pad 42 deposited on a cathode electrode 3 at the bottom of a groove made in the electrical insulation layer 7 and between an element conductor 51 of a first control electrode 5 'and a conductive member 62 of a second control electrode 6; in operation, by applying a voltage V5, to the first control electrode 5 'which is greater than the voltage V6 of the second control electrode 6, an electric field dissymmetry is created at the level of the cathodo-emissive pad 42, which is translated by a decrease in the divergence of the electron beam F 'emitted by this pad. On one of the control electrodes, the extraction voltage of the prior art is maintained (typical value: V6 = 60V-100V) and on the other control electrode 5 'a lower control voltage is applied. V5, (may be negative). As a result, the electrons emitted at the potential OV (or at a positive potential of a few volts if there is a resistive layer) of the cathodo-emissive pad 42 will preferentially be attracted to the connected conductive electrode conductive element 62. at high potential V6. This gives a focusing effect which has the effect of reducing the divergence of the beam. Overall, it has been found that this focusing effect makes it possible to substantially improve the quality of the image display. Returning to FIG. 2, in particular the sectional view (right-hand part of the figure), it can be seen that in order to maintain a sufficiently homogeneous distribution of the electrons on the anodic front panel (not shown), it is important to redistribute the position of the lines L 1, 2, 3 of cathodo-emissive pads relative to that of lines L1, L2, L3 of the prior art (see FIG. 1), so that the distance between the adjacent elements 51, 52 of the control electrode 5 'subject to the potential V5, the smaller is greater than the distance between the adjacent elements 61, 62 of the control electrode 6 subjected to the potential V6, the highest. That is why it is preferable that the distance between the adjacent lines 1, 2, 3 of cathodo-emissive pads varies by at least a factor of 1.5. The present invention has been described with reference to cathode elements comprising three lines of cathodo-emissive pads; it is obvious to those skilled in the art that it can be applied to other types of cathode elements and to other types of EDF display panels without departing from the scope of the following claims.

Claims (10)

  A cathode element (1 ') comprising a cathode substrate (2), a cathode electrode (3'), a plurality of cathodo-emissive pads (41, 42, 43) which are distributed in at least three lines (L1, L2, L3) and which are electrically connected to said cathode electrode (3), a first control electrode (5 ') comprising conductive elements (51, 52), characterized in that it comprises a second control electrode ( 6) comprising other conductive elements (61, 62) and in that each line (L1, L2, L3) of cathodo-emissive pads (41, 42, 43) is interposed between a conductive element (51, 52) of said first control electrode (5 ') and a conductive member (61, 62) of said second control electrode (6).   2. cathode element (1 ') according to claim 1 characterized in that the distance between the adjacent lines (L'1, L'2, L'3) of cathodo-emissive pads varies by at least a factor 1.5 .   3. cathode element (1 ') according to claim 1 or 2 characterized in that it comprises an electrical insulation layer (7) interposed between firstly said cathode electrode (3') and secondly the first (5 ') and the second (6) control electrode.   4. cathode element (1) according to any one of the preceding claims characterized in that the first (5 ') and the second (6) control electrode are coplanar.   5. cathode element (1) according to any one of the preceding claims characterized in that each cathodo-emissive pad (41, 42, 43) is based on carbon nanotubes.   6. cathode element (1) according to any one of the preceding claims characterized in that said cathodo-emissive pads (41, 42, 43) are electrically connected to said cathode electrode (3) via a resistive layer spacer.   An image display panel comprising an array of cathodoluminescent transmitters, characterized in that each cathode-emitter comprises a cathode element according to any one of the preceding claims.   8. Panel according to claim 7, characterized in that said cathodoluminescent transmitters being distributed in rows and in column, the set of cathodic elements cathodoluminescent transmitters of each column shares the same cathode electrode, and all of the cathode elements of Cathodoluminescent transmitters from each line share the same first and the same second control electrode.   9. An image display method using the panel according to claim 7 or 8, wherein is displayed using a cathodoluminescent transmitter of said panel each pixel, and, where appropriate, each sub-pixel , of said image, characterized in that, for the display of each transmitter, the voltage V5 applied to the first control electrode is lower than the voltage V6 applied to the second control electrode of said transmitter.   10. The method of claim 9 characterized in that the distance between the adjacent elements (51, 52) of the first control electrode (5 ') is greater than the distance between the adjacent elements (61, 62) of the second electrode order form (6) .20