Patent Description:
This disclosure relates to processes for producing electro-optic displays and. More specifically, this invention relates to processes for the production of electro-optic displays without the use of front plane laminates, inverted front plane laminates and double release films as described in the aforementioned <CIT>; <CIT>; and <CIT>, and to processes for depositing encapsulated electrophoretic media by spraying.

The term "electro-optic", as applied to a material or a display, is used herein in its conventional meaning in the imaging art to refer to a material having first and second display states differing in at least one optical property, the material being changed from its first to its second display state by application of an electric field to the material. Although the optical property is typically color perceptible to the human eye, it may be another optical property, such as optical transmission, reflectance, luminescence or, in the case of displays intended for machine reading, pseudo-color in the sense of a change in reflectance of electromagnetic wavelengths outside the visible range.

The term "gray state" is used herein in its conventional meaning in the imaging art to refer to a state intermediate two extreme optical states of a pixel, and does not necessarily imply a black-white transition between these two extreme states. The term "monochrome" may be used hereinafter to denote a drive scheme which only drives pixels to their two extreme optical states with no intervening gray states.

Some electro-optic materials are solid in the sense that the materials have solid external surfaces, although the materials may, and often do, have internal liquid- or gas-filled spaces. Such displays using solid electro-optic materials may hereinafter for convenience be referred to as "solid electro-optic displays". Thus, the term "solid electro-optic displays" includes rotating bichromal member displays, encapsulated electrophoretic displays, microcell electrophoretic displays and encapsulated liquid crystal displays.

Several types of electro-optic displays are known, for example.

<CIT> describes a method for bonding substrates, a touch substrate and a display device, and <CIT> as well as <CIT> are relevant prior art documents.

One type of electro-optic display, which has been the subject of intense research and development for a number of years, is the particle-based electrophoretic display, in which a plurality of charged particles move through a fluid under the influence of an electric field. Electrophoretic displays can have attributes of good brightness and contrast, wide viewing angles, state bistability, and low power consumption when compared with liquid crystal displays. Nevertheless, problems with the long-term image quality of these displays have prevented their widespread usage. For example, particles that make up electrophoretic displays tend to settle, resulting in inadequate service-life for these displays.

As noted above, electrophoretic media require the presence of a fluid. In most prior art electrophoretic media, this fluid is a liquid, but electrophoretic media can be produced using gaseous fluids; see, for example, <NPL>, and <NPL>). See also <CIT> and <CIT>. Such gas-based electrophoretic media appear to be susceptible to the same types of problems due to particle settling as liquid-based electrophoretic media, when the media are used in an orientation which permits such settling, for example in a sign where the medium is disposed in a vertical plane. Indeed, particle settling appears to be a more serious problem in gas-based electrophoretic media than in liquid-based ones, since the lower viscosity of gaseous suspending fluids as compared with liquid ones allows more rapid settling of the electrophoretic particles.

Numerous patents and applications assigned to or in the names of the Massachusetts Institute of Technology (MIT) and E Ink Corporation describe various technologies used in encapsulated electrophoretic and other electro-optic media. Such encapsulated media comprise numerous small capsules, each of which itself comprises an internal phase containing electrophoretically-mobile particles in a fluid medium, and a capsule wall surrounding the internal phase. Typically, the capsules are themselves held within a polymeric binder to form a coherent layer positioned between two electrodes. The technologies described in these patents and applications include:.

Many of the aforementioned patents and applications recognize that the walls surrounding the discrete microcapsules in an encapsulated electrophoretic medium could be replaced by a continuous phase, thus producing a so-called polymer-dispersed electrophoretic display, in which the electrophoretic medium comprises a plurality of discrete droplets of an electrophoretic fluid and a continuous phase of a polymeric material, and that the discrete droplets of electrophoretic fluid within such a polymer-dispersed electrophoretic display may be regarded as capsules or microcapsules even though no discrete capsule membrane is associated with each individual droplet; see for example, the aforementioned <CIT>. Accordingly, for purposes of the present application, such polymer-dispersed electrophoretic media are regarded as sub-species of encapsulated electrophoretic media.

Although electrophoretic media are often opaque (since, for example, in many electrophoretic media, the particles substantially block transmission of visible light through the display) and operate in a reflective mode, many electrophoretic displays can be made to operate in a so-called "shutter mode" in which one display state is substantially opaque and one is light-transmissive. See, for example, <CIT>; <CIT>; <CIT>; <CIT>; <CIT>; <CIT>; and <CIT>. Dielectrophoretic displays, which are similar to electrophoretic displays but rely upon variations in electric field strength, can operate in a similar mode; see <CIT>. Other types of electro-optic displays may also be capable of operating in shutter mode. Electro-optic media operating in shutter mode may be useful in multi-layer structures for full color displays; in such structures, at least one layer adjacent the viewing surface of the display operates in shutter mode to expose or conceal a second layer more distant from the viewing surface.

An encapsulated electrophoretic display typically does not suffer from the clustering and settling failure mode of traditional electrophoretic devices and provides further advantages, such as the ability to print or coat the display on a wide variety of flexible and rigid substrates. (Use of the word "printing" is intended to include all forms of printing and coating, including, but without limitation: pre-metered coatings such as patch die coating, slot or extrusion coating, slide or cascade coating, curtain coating; roll coating such as knife over roll coating, forward and reverse roll coating; gravure coating; dip coating; spray coating; meniscus coating; spin coating; brush coating; air knife coating; silk screen printing processes; electrostatic printing processes; thermal printing processes; ink jet printing processes; electrophoretic deposition (See <CIT>); and other similar techniques. ) Thus, the resulting display can be flexible. Further, because the display medium can be printed (using a variety of methods), the display itself can be made inexpensively.

The aforementioned <CIT> describes a method of assembling a solid electro-optic display (including an encapsulated electrophoretic display) which is well adapted for mass production. Essentially, this patent describes a so-called "front plane laminate" ("FPL") which comprises, in order, a light-transmissive electrically-conductive layer; a layer of a solid electro-optic medium in electrical contact with the electrically-conductive layer; an adhesive layer; and a release sheet. Typically, the light-transmissive electrically-conductive layer will be carried on a light-transmissive substrate, which is preferably flexible, in the sense that the substrate can be manually wrapped around a drum (say) <NUM> inches (<NUM>) in diameter without permanent deformation. The term "light-transmissive" is used in this patent and herein to mean that the layer thus designated transmits sufficient light to enable an observer, looking through that layer, to observe the change in display states of the electro-optic medium, which will normally be viewed through the electrically-conductive layer and adjacent substrate (if present); in cases where the electro-optic medium displays a change in reflectivity at non-visible wavelengths, the term "light-transmissive" should of course be interpreted to refer to transmission of the relevant non-visible wavelengths. The substrate will typically be a polymeric film, and will normally have a thickness in the range of about <NUM> to about <NUM> mil (<NUM> to <NUM>), preferably about <NUM> to about <NUM> mil (<NUM> to <NUM>). The electrically-conductive layer is conveniently a thin metal or metal oxide layer of, for example, aluminum or ITO, or may be a conductive polymer. Poly(ethylene terephthalate) (PET) films coated with aluminum or ITO are available commercially, for example as "aluminized Mylar" ("Mylar" is a Registered Trade Mark) from E. du Pont de Nemours & Company, Wilmington DE, and such commercial materials may be used with good results in the front plane laminate.

Assembly of an electro-optic display using such a front plane laminate may be effected by removing the release sheet from the front plane laminate and contacting the adhesive layer with the backplane under conditions effective to cause the adhesive layer to adhere to the backplane, thereby securing the adhesive layer, layer of electro-optic medium and electrically-conductive layer to the backplane. This process is well-adapted to mass production since the front plane laminate may be mass produced, typically using roll-to-roll coating techniques, and then cut into pieces of any size needed for use with specific backplanes.

The aforementioned <CIT> describes a so-called "double release sheet" which is essentially a simplified version of the front plane laminate of the aforementioned <CIT>. One form of the double release sheet comprises a layer of a solid electro-optic medium sandwiched between two adhesive layers, one or both of the adhesive layers being covered by a release sheet. Another form of the double release sheet comprises a layer of a solid electro-optic medium sandwiched between two release sheets. Both forms of the double release film are intended for use in a process generally similar to the process for assembling an electro-optic display from a front plane laminate already described, but involving two separate laminations; typically, in a first lamination the double release sheet is laminated to a front electrode to form a front sub-assembly, and then in a second lamination the front sub-assembly is laminated to a backplane to form the final display, although the order of these two laminations could be reversed if desired.

The aforementioned <CIT> describes a so-called "inverted front plane laminate", which is a variant of the front plane laminate described in the aforementioned <CIT>. This inverted front plane laminate comprises, in order, at least one of a light-transmissive protective layer and a light-transmissive electrically-conductive layer; an adhesive layer; a layer of a solid electro-optic medium; and a release sheet. This inverted front plane laminate is used to form an electro-optic display having a layer of lamination adhesive between the electro-optic layer and the front electrode or front substrate; a second, typically thin layer of adhesive may or may not be present between the electro-optic layer and a backplane. Such electro-optic displays can combine good resolution with good low temperature performance.

As already indicated, the aforementioned front plane laminates, inverted front plane laminates and double release films are well adapted for production by roll-to-roll processes, thus producing the front plane laminate, inverted front plane laminate or double release film in the form of a roll of material which can be severed into pieces of the size needed for individual displays and laminated to appropriate backplanes. However, also as already indicated, to effect the necessary lamination, and layer of lamination adhesive normally needs to be present between the electro-optic layer itself and the backplane, and this layer of lamination adhesive remains in the final display between the two electrodes. The presence of this lamination adhesive layer has significant effects on the electro-optic properties of the display. Inevitably, some of the voltage drop between the electrodes occurs within the lamination adhesive layer, thus reducing the voltage available for driving the electro-optic layer. The effect of the lamination adhesive tends to become greater at lower temperatures, and this variation in the effect of lamination adhesive with temperature complicates the driving of the display. The voltage drop within the lamination adhesive can be reduced, and the low temperature operation of the display improved, by increasing the conductivity of the lamination adhesive layer, for example by doping the layer with tetrabutylammonium hexafluorophosphate or other materials as described in <CIT> and <CIT>. However, increasing the conductivity of the lamination adhesive layer in this manner tends to increase pixel blooming (a phenomenon whereby the area of the electro-optic layer which changes optical state in response to change of voltage at a pixel electrode is larger than the pixel electrode itself), and this blooming tends to reduce the resolution of the display. Hence, this type of display apparently intrinsically requires a compromise between low temperature performance and display resolution.

The present invention relates to processes for the production of electro-optic displays which do not require the presence of a lamination adhesive layer between the electro-optic layer and the backplane; these processes involve coating the electro-optic material on to the backplane.

A second aspect which is not part of the present invention relates to novel processes for application of encapsulated electrophoretic media to substrates. These processes may be used to aid in the first aspect of the invention but may also be used in other types of coating processes.

The electrophoretic media described in the aforementioned E Ink patents and applications, and similar prior art electrophoretic media typically comprise electrophoretic particles, charge control agents, image stability agents and flocculants in a non-polar liquid, typically encapsulated in a flexible organic matrix such as a gelatin/acacia coacervate. To produce commercial displays, it is necessary to coat a thin layer (preferably a monolayer - see <CIT>) of capsules on a substrate, which may be a front substrate bearing an electrode (see the aforementioned <CIT>), a backplane or a release sheet. Hitherto, coating of encapsulated electrophoretic media on substrates has typically been effected by slot coating, in which a slurry of capsules in a carrier medium is forced through a slot on to a substrate which is moving relative to the slot. Slot coating imposes limitations upon the viscosity and other physical properties of the material being coated and typically requires the addition of slot coating additives to control the rheology of the coated material to ensure that the coating does not flow and develop non-uniformities in thickness prior to drying. Thus, in slot coating electrophoretic capsules are typically supplied in the form of aqueous slurries containing optional latex binder, rheology modification agents, ionic dopants, and surfactants. These additives remain in the final dried electrophoretic medium and may affect its properties, including its electro-optic properties.

Furthermore, although slot coating is well adapted for applying electrophoretic media to continuous webs, it is not well adapted for "patch" coating of discrete areas of a web or discrete parts (for example, individual backplanes) lying on a moving belt, since settling and self-segregation of capsule slurry within the slot die manifold become problematic during such "interrupted" capsule deposition processes. Slot coating is generally not useful for non-planar substrates, which is unfortunate since encapsulated electrophoretic media are well adapted for coating three-dimensional objects, including architectural features. Other problems with slot coating include chatter-like streaks parallel to the coating slot die (these streaks are believed to result from periodic bunching or jamming of capsules), and streaking in the direction of coating (believed to be due to capsule jamming or non-uniform flows in delivery of capsules to the slot coating slot die).

The aforementioned problems with slot coating have resulted in a search for an alternative coating technology able to cope with patch coating and coating of non-planar substrates, as well as planar objects and webs. One well established coating technology which has been considered for this purpose is spray coating, i.e., the pneumatic atomization and deposition of capsule dispersions. Spray coating is a mature technology, but prior art attempts to apply the technology to capsule deposition have been subject to various defects and modes of failure. Because they typically have flexible capsule walls, capsules deform and sometime rupture during spraying, either during the atomization step or upon impact on the target. The consequences of significant capsule rupture, including the release of electrophoretic particles, fluid etc., are so severe that, so far as the present inventors are aware, unacceptable levels of ruptured capsules have by themselves been sufficient to doom all previous attempts to spray coat encapsulated electrophoretic media. The second aspect of the present invention provides a spray coating process which reduces or eliminates these problems.

A third aspect which is not part of the present invention relates to processes for reducing the adhesion of capsules to a substrate during coating in order to facilitate close packing of capsules on the substrate. This adhesion reduction process is primarily intended for use with spray coating of capsules but may also be useful with other capsule deposition techniques.

As previously mentioned, in the production of electrophoretic displays it is generally preferred to form a monolayer of capsules on a substrate. However, a common problem encountered when coating electrophoretic capsules on to a substrate (typically a ITO/PET film, a PET/release film, or any type of silicone release film) is that the capsules adhere strongly to the substrate and are unable to rearrange themselves into an optimally packed monolayer upon drying. Various coating materials have been found to significantly reduce capsule-substrate adhesion, thus allowing the capsules to rearrange themselves by means of capillary forces during drying. Unfortunately, if such coating materials are used in slot coating processes employing a doctor blade, as is common during slot coating, the reduced capsule-substrate adhesion causes the capsules to not pass properly past the doctor blade; instead, the vast majority of the capsules are simply pushed in front of the doctor blade, leaving only a very sparse capsule coating on the substrate. Accordingly, there is a need for an improved process for the formation of closely packed monolayers of capsules on substrates, and the third aspect seeks to provide such a process.

A fourth aspect not forming part of the present invention relates to processes for overcoating electro-optic materials to planarize an electro-optic layer and/or adhere the electro-optic layer to a transparent front electrode that may be attached to a color filter.

It is known (see especially <CIT>) that a color display may be formed by overlaying a color filter array (CFA) over an monochromatic black/white electro-optic display, with the CFA elements aligned with the pixel electrodes of the backplane. Such a CFA may for example have repeating red, green and blue stripes, or a repeating <NUM> x <NUM> red/green/blue/white (clear) pixel pattern. The brightest state of such a display is achieved when all pixels of the electro-optic layer are white, and it is therefore preferred that the absorption of the CFA elements, taken as a whole, be constant across the visible range, so that the brightest state will have no color tint.

Overlaying a CFA over an electro-optic layer in this manner leads to a trade-off between brightness and color saturation, and the colors that are most difficult to render are the brightest colors, such as white and yellow. Moreover, such a display suffers from several sources of light loss or contamination that limit still further the quality of color attainable. These include:.

When an electro-optic display is formed using a front plane laminate, as described above with reference to <CIT>, a single adhesive layer is present between the electro-optic layer and the backplane. Although this adhesive layer is not disposed between the electro-optic layer and the CFA (and thus does not contribute to most of the problems discussed above), it is present between the electrodes of the display, and thus contributes to image blooming. The presence of this adhesive layer also diminishes the voltage drop actually occurring across the electro-optic layer, which tends to limit the reflectivity of the white state of the electro-optic layer and its contrast ratio. When an electro-optic display is formed using either a double release film, as described above with reference to <CIT>, or an inverted front plane laminate, as described above with reference to <CIT>, typically two adhesive layers will be present, the first between the CFA and the electro-optic layer, and the second between the electro-optic layer and the backplane. The second adhesive layer contributes to the same problems as the adhesive layer derived from an FPL, as already discussed; the first adhesive layer at least contributes to the illumination and viewing parallax problems, and may also contribute to the total internal reflection problem.

There is thus a need for a process for producing electro-optic displays which reduces or eliminates the problems caused by the presence of adhesive layers between the electrodes. However, since as discussed above, manufacture of electro-optic displays necessitates at least one lamination operation, the best process will involve the provision of only one thin adhesive layer, and the present invention seeks to provide such a process.

Accordingly, in one aspect this invention provides a process for producing a sub-assembly for use in an electro-optic display, the process being as defined in appended claim <NUM>.

This process may hereinafter for convenience be referred to as the "masked backplane" process of the invention. In one form of this process, the second area of the backplane comprises a contact pad intended, in the final display, to make electrical contact with the front electrode of the display. In this form of the invention, a light-transmissive conductive layer may be partially covered with a lamination adhesive, and laminated to the backplane/electro-optic material sub-assembly with the lamination adhesive contacting the electro-optic material and the light-transmissive conductive layer in electrical contact with the contact on the backplane. This electrical contact may be direct, or may be made via an electrically conductive ink or similar deformable conductive material.

In another form of the process, after the layer of electro-optic material has been coated on the backplane, but before the masking layer is removed, a layer of lamination adhesive (preferably a <NUM> per cent solids radiation-curable adhesive) is coated over the electro-optic material, and then the masking layer is removed, together with both the portions of the layers of electro-optic material and the lamination adhesive thereon. A light-transmissive electrically-conductive layer can then be laminated to the lamination adhesive in the first area of the backplane; the light-transmissive electrically-conductive layer preferably extends into the second area of the backplane so as to make electrical contact with the contact pad in this second area.

In a further form of the process, the backplane has a third area which is covered by a second masking layer which can be removed separately from the (first) masking layer covering the second area. In this form of the process, after the layer of electro-optic material has been coated, the second masking layer is removed, thus exposing the third area of the backplane. Alight-transmissive electrically-conductive layer is now coated over the backplane.

In a second aspect not forming part of the claimed invention provides a process for spraying capsules of an electrophoretic medium on to a substrate, the process comprising:.

This process may hereinafter for convenience be referred to as the "spray coating process". The process may include shaping the spray by feeding a continuous stream of gas through a plurality of shaping orifices disposed adjacent the spray. The spray may be directed on to any type of substrate, including a web, a plurality of discrete objects disposed on a support or one or more three-dimensional (i.e., non-planar) objects. If, as is typically the case, the capsule walls are formed from a hydrophilic material (such as the aforementioned gelatin/acacia coacervate), the liquid used to disperse the capsules is desirably aqueous; depending upon the specific capsules and liquid used, the liquid may optionally comprise any one or more of pH modifiers, surfactants and ionic dopants. The gas passed through both the second orifice and the shaping orifices is typically air, but it some cases it may be useful to use an inert gas, for example nitrogen.

The spray coating process may include the use of a masking material covering part of the substrate so that, after removal of the masking material, capsules remain only on those portions of the substrate where the masking material was not present. Such a "masked spray coating process" of the invention may comprise multiple steps with each step involving the use of a different mask and a different capsule dispersion so that the different capsule dispersions are disposed in different areas of the final display.

In a third aspect not forming part of the claimed invention provides a process for forming a monolayer of capsules on a substrate, the process comprising:.

This process may hereinafter for convenience be referred to as the "swellable polymer coating process". The polymer used may be, for example, a polysaccharide, such as a pectin, or a protein, especially an albumin. The albumin used may be, for example, egg albumin or bovine serum albumin; other types of albumin may also be suitable. At least when the capsules are formed of a hydrophilic material (such as the gelatin/acacia coacervate mentioned in many of the E Ink patents and applications mentioned above), the polymer solution is preferably an aqueous solution. The deposition of the capsules is desirably effected by a process such as spray coating which does not require contact of a coating head or coating bar with the capsule layer.

In a fourth aspect not forming part of the claimed invention provides a process for forming an electro-optic display, the process comprising:.

This process may hereinafter for convenience be referred to as the "overcoat layer process". In this process, the coating of the backplane with the electro-optic material may be conducted by the masked backplane process of the present invention (to permit masking of any areas, for example row and column electrodes, which should not be covered by electro-optic material) and/or by the spray coating process of the present invention.

In one form of the overcoat layer process of the present invention, both a light-transmissive electrically-conductive layer and a color filter array are adhered to the electro-optic layer. Typically, the light-transmissive electrically-conductive layer is mounted on a front substrate, which is provided with a color filter array (which may be printed directly on to the front substrate). The front substrate may serve to provide mechanical support to the electrically-conductive layer; many conductive layers, for example indium-tin-oxide (ITO) layers are too fragile to be self-supporting.

In a second form of the overcoat layer process the electro-optic layer is a color electro-optic layer capable of displaying a variety of colors (a so-called "inherent color" layer), and only a front plane electrode (and any supporting substrate required) are adhered to the electro-optic layer by means of the polymerizable liquid material.

As already indicated, this disclosure has several different aspects, which will primarily be described separately below.

As indicated above, the masked backplane process of the present invention provides a process for producing a sub-assembly for use in an electro-optic display. This process comprises providing a backplane comprising at least one electrode located in a first area of the backplane; covering a second area of the backplane spaced from the electrode with a masking layer; coating the backplane having the masking layer thereon with a layer of an electro-optic material; and removing the masking layer, and the portion of the layer of electro-optic medium thereon, from the backplane, thereby producing a sub-assembly comprising the backplane having its first area covered by the layer of electro-optic material but its second area free from the layer of electro-optic material. Thus, the masked backplane process allows for formation of a sub-assembly, and ultimately an electro-optic display, without the use of a pre-formed front plane laminate and without the presence of a lamination adhesive layer between the electro-optic layer and the backplane, thus reducing or eliminating the problems associated with this lamination adhesive layer, as discussed above.

The masked backplane process of the present invention builds the sub-assembly or display starting from the backplane. The process may be carried out on individual backplanes but for mass production purposes it is more conveniently effected on backplanes arranged in a multi-up configuration. Conceptually, when used to produce a complete display, the masked backplane process may be regarded as involving (a) the backplane itself, which may be a segmented, passive matrix or active matrix backplane; (b) a masking layer for protecting areas of the backplane which are not be covered by the electro-optic material (the protected areas will typically be those required for making a "top plane connection" to the front electrode of the final display, and may also include areas used for conductors leading to the pixel electrodes and electronic components such as row and column drivers); (c) a solid electro-optic medium, typically an encapsulated electrophoretic medium; (d) a light-transmissive, electrically-conductive layer which forms the front electrode of the display; and (e) a means, typically a lamination adhesive, for securing the light-transmissive, electrically-conductive layer to the solid electro-optic medium.

As already indicated, the backplane used in the masked backplane process may be of any known type, although care should be taken to ensure that the backplane used does not damage the electro-optic layer. For example if the electro-optic layer is to be formed from an encapsulated electrophoretic medium, the backplane should not have such sharp changes in level as to risk puncturing some of the capsules. The masking layer may be formed from a simple polymeric film which adheres to the backplane either because of its own physical properties or with the aid of an adhesive coating, but should desirably not be more than about <NUM> in thickness; polymeric films which have been found useful as masking layers include Kapton tape (a polyimide tape available from du Pont de Nemours & Company, Wilmington, DE) and RP301 film (an acrylic film available form Nitto America, Inc. , Fremont CA). The solid electro-optic layer is typically an encapsulated electrophoretic layer but may also be a polymer-dispersed electrophoretic layer or a rotating bichromal member or electrochromic layer. Care should be taken to ensure that the physical properties of the electro-optic layer are such that the portions of the layer overlying the masking layer are removed when the masking layer itself is removed, without tearing the masking layer so that portions of the masking layer are left on the backplane and/or without portions of the electro-optic layer in the unmasked portion of the backplane being inadvertently removed. The material used to form the front electrode and the adhesive can be any of the materials used in the prior art for this purpose.

Specific masked backplane processes of the invention will now be described in more detail with reference to <FIG> of the accompanying drawings. <FIG> is a top plan view of an active matrix backplane (generally designated <NUM>) having a first, central area <NUM> provided with a two dimensional array of pixel electrodes (not shown), and a second, peripheral area <NUM> covered by a masking film <NUM>. (It will be appreciated that the relative sizes and dispositions of the first and second areas <NUM> and <NUM> can vary widely and it is not necessary that the second area <NUM> surround the first area <NUM>. ) The second area <NUM> will normally include a contact pad for making electrical contact with a front electrode (described below) and may include row and column electrodes connected to the pixel electrodes in the first area <NUM> and sockets for row and column drivers.

After provision of the masking layer on the backplane, the next step of the masked backplane process is coating the backplane with a layer of electro-optic material <NUM>, as illustrated in <FIG>. Any technique capable of depositing the layer of electro-optic material on the backplane may be used to form layer <NUM>; with an encapsulated electrophoretic electro-optic material, slot die coating, bar coating and spray coating methods have all been successfully used to apply the electrophoretic material directly to a masked backplane. Depending upon the deposition method used, the layer of electro-optic material may or may not cover completely both the first and second areas of the backplane; for example, some spray coating methods may only coat part of the masked area.

The next step of the process is removal of the masking layer <NUM> to expose the second area <NUM> of the backplane <NUM>, and the electrical connectors and/or sockets thereon, as illustrated in <FIG>. As already noted, it is important to choose the masking layer and the electro-optic material such that the masking film and overlying layer of electro-optic material are removed completely from the second area <NUM> but that no portion of the electro-optic material overlying the first area <NUM> is removed.

To complete the assembly of an electro-optic display, it is necessary to secure a light-transmissive, electrically conductive layer over the layer of electro-optic material <NUM>. As shown in <FIG>, this is most conveniently effected by providing a front substrate <NUM> carrying the light-transmissive, electrically conductive layer or front electrode layer <NUM>. As discussed for example in the aforementioned <CIT>, polymeric films coated with indium tin oxide (ITO) are available commercially and are very suitable for providing the front substrate <NUM> and front electrode layer <NUM>. A layer of lamination adhesive <NUM> is then formed on the front electrode layer <NUM>, leaving exposed a portion of the front electrode layer <NUM> needed to provide an electrical connection to the backplane <NUM>. In practice, it is generally most convenient to coat the whole of the front electrode layer <NUM> with the lamination adhesive layer <NUM> using a roll-to-roll process, cut the resultant roll into portions of the size needed for individual displays, and then to remove or "clean" the lamination adhesive from the portion of the front electrode layer <NUM> required to provide the electrical connection. A variety of methods for cleaning the lamination adhesive from the requisite portion of the front electrode layer <NUM> are known in the art; see, for example, <CIT>.

The sub-assembly shown in <FIG> is then laminated to the sub-assembly shown in <FIG> with the lamination adhesive layer <NUM> in contact with the electro-optic layer <NUM> to form the final display shown in <FIG>. Typically, a conductive ink or similar material <NUM> is placed on the backplane <NUM> adjacent the portion of the front electrode layer <NUM> not covered by the adhesive layer <NUM>, as described in the aforementioned <CIT>. This final display has the advantage that the electro-optic layer <NUM> is in direct contact with the backplane <NUM> (without any intervening adhesive layer), thereby maximizing the resolution of the display. In addition, the positioning of the adhesive layer <NUM> adjacent the front electrode layer <NUM> allows the adhesive layer <NUM> to be made highly conductive without detriment to the resolution of the display.

<FIG> illustrate a second masked backplane process of the invention in which an adhesive layer is formed overlying the electro-optic layer before the masking layer is removed. The first stages of this second process, namely the provision of a masking layer <NUM> on a backplane <NUM> and the deposition of an electro-optic layer <NUM> over the backplane, are identical to the first process described above, and result in the sub-assembly shown in <FIG>, which is essentially identical to that shown in <FIG>. However, the next step in the second process is the coating of a <NUM> per cent solids radiation-curable adhesive layer <NUM> over the electro-optic layer <NUM>, to produce the structure shown in <FIG>. The adhesive layer <NUM> is left uncured at this step of the process. The masking layer <NUM> is next removed, as shown in <FIG>, thereby removing the portions of both the electro-optic layer <NUM> and the adhesive layer <NUM> previously overlying the masking layer <NUM>. Again, it is important to choose the masking layer, the electro-optic material and the adhesive such that the masking film and overlying layers of electro-optic material and adhesive are removed completely from the second area <NUM> but that no portion of the electro-optic material overlying the first area <NUM> is removed.

The final step in the second process is the lamination of a film comprising a front substrate <NUM> and front electrode layer <NUM> to the sub-assembly shown in <FIG> to produce the final display shown in <FIG>, with the provision of conductive ink <NUM> or similar conductive material as described above with reference to <FIG>. Since the radiation-curable adhesive layer <NUM> is already present in the sub-assembly of <FIG>, no further adhesive is needed and the front substrate <NUM> and front electrode layer <NUM> can be laminated at substantially room temperature and without the use of high pressure. The use of the <NUM>% solids adhesive layer <NUM> allows the front electrode layer <NUM> and front substrate <NUM> to take a variety of forms including flexible substrates and also rigid substrates like glass. Once the front electrode layer <NUM> and front substrate <NUM> have been applied, the adhesive layer <NUM> can be radiation cured with ultraviolet radiation to produce the final display shown in <FIG>. This display, like that shown in <FIG>, has the advantage that the electro-optic layer <NUM> is in direct contact with the backplane <NUM> to maximize the resolution of the display. In addition, the positioning of the adhesive layer <NUM> adjacent the front electrode layer <NUM> allows the adhesive layer <NUM> to be made highly conductive without detriment to the resolution of the display. The process of <FIG> eliminates the top plane cleaning used in the process of <FIG>, allows for a thinner adhesive layer because this layer is applied as a liquid, allows for flexible or rigid front electrode layers and eliminates the need for a high temperature lamination step.

<FIG> illustrate a third masked backplane process of the invention in which two separate masking layers are used and a front electrode layer is formed directly on the electro-optic layer. The first stages of this third process, namely the provision of two separate masking layers 106A and 106B on a backplane <NUM> and the deposition of an electro-optic layer <NUM> over the backplane, are generally similar to the first and second processes described above, and result in the sub-assembly shown in <FIG>, which is generally similar to those shown in <FIG> and <FIG> except for the provision of the two separate masking layers 106A and 106B. Masking layer 106A covers the bonding areas for the driver electronics and edge seal areas, while masking layer 106B covers the area for front electrode connection(s). The two masking layers do not have to be separate films but can be in the form of a single film cut to allow two portions thereof to be removed separately, as illustrated schematically in <FIG>. Alternatively, depending upon the geometry of the areas covered by the first and second masking films, the first masking film may cover all areas of the backplane which are not to have electro-optic material deposited thereon, and the second masking film may be a separate film applied over the first masking film. The masking films previously described can be used. The masked backplane shown in <FIG> then has electro-optic material deposited thereon by any of the methods previously described to produce the structure shown in <FIG>.

The next step in the second process is removal of the second masking layer 106B without removing the first masking layer 106A, thus exposing the areas of the backplane needed for front electrode contacts, and producing the structure shown in <FIG>. Next, a light-transmissive, electrically-conductive front electrode layer <NUM> is deposited (normally by a wet coating process) over the backplane to produce the structure shown in <FIG>. The front electrode layer <NUM> not only forms a front electrode over the electro-optic layer <NUM> but also forms a front electrode connection with the exposed areas of the backplane, as illustrated at the right hand side of <FIG>. The front electrode layer <NUM> may be formed from a conductive polymer, for example poly(<NUM>,<NUM>-ethylenedioxythiophene) ("PEDOT"), normally used in the form of its poly(styrenesulfonate) salt ("PEDOT:PSS") or a polyaniline, or may be formed from network of conductors, for example carbon nanotubes or nanowires. The present inventors have successfully coated both PEDOT and carbon nanotube front electrodes directly on an encapsulated electrophoretic layer.

The final step of the process is removal of the first masking layer 106A, together with the overlying portions of the electro-optic layer <NUM> and the front conductor layer <NUM> to produce the display illustrated in <FIG>. If desired driver electronics and/or edge seals may now be placed in the exposed areas of the backplane.

The display shown in <FIG>, like those shown in <FIG> and <FIG>, has the advantage that the electro-optic layer is in direct contact with the backplane, thus maximizing the resolution of the display. However, in contrast to the displays described above, the display shown in <FIG> has no lamination adhesive between its electrodes, thus completely eliminating the electrical effect of such adhesive. Thus, the display structure shown in <FIG> enables the highest resolution and temperature performance for a given electro-optic layer. One potential practical problem with the display structure shown in <FIG> is that any pore or pinhole in the electro-optic layer would allow the coated front electrode to come into electrical contact with the pixel electrodes on the backplane, thus shorting the display.

From the foregoing, it will be seen that the masked backplane process of the present invention can provide high resolution addressing without compromising temperature performance, thus removing the limitations imposed by prior art display construction methods which require a thin adhesive between the electro-optic layer and the backplane. Additionally the masked backplane process opens up the possibility of conducting the entire manufacturing process in a single fab.

As already mentioned, this disclosure also provides a process for spraying capsules of an electrophoretic medium on to a substrate. This process comprises forming a dispersion of the capsules in a liquid; feeding the dispersion through a first orifice; and feeding a continuous stream of gas through a second, annular orifice surrounding the first orifice, thereby forming a spray of the capsules. This spray coating process has the advantage over slot coating that spray coating normally does not require the use of rheology modifiers in the liquid being sprayed, so that the final coating is free from such rheology modifiers and hence free from the effects such rheology modifiers may have upon the properties of slot coated electrophoretic media. Typically, in spray coating, only the additives actually needed in the final product need be added to the liquid being sprayed.

<FIG> is a schematic cross-section through a simple spray coating nozzle (generally designated <NUM>) which may be used in the spray coating process of the present invention. The nozzle <NUM> comprises a substantially cylindrical body <NUM> having a central, axial bore <NUM> through which is pumped electrophoretic capsules (not shown) dispersed in a liquid (also not shown). The central bore <NUM> is surrounded by an annular bore <NUM>, through which is forced a continuous stream of air. The lower end of the central bore <NUM> terminates in an orifice <NUM>, which the lower end of the annular bore <NUM> terminates in an annular orifice <NUM>, which surrounds orifice <NUM>. A cylindrical baffle <NUM> surrounds the annular orifice <NUM>. The air flow through the annular orifice <NUM> constrained by the baffle <NUM> causes the dispersion of capsules passing through orifice <NUM> to form a spray or jet <NUM>.

The nozzle <NUM> is also provided with shaping air bores <NUM>, which may be six or eight in number. As shown in <FIG>, the peripheral portions of the nozzle <NUM>, through which the bores <NUM> pass, extend downwardly below the orifices <NUM> and <NUM> and the baffle <NUM>, and the lower portions of the bores <NUM> are directly downwardly and inwardly. Shaping air is forced continuously through the bores <NUM> so that it impinges on the jet <NUM>, thereby causing the jet to open out into a wide spray <NUM>, which impinges on a substrate <NUM> disposed below the nozzle <NUM>.

<FIG> and <FIG> illustrate a high-volume low-pressure atomization nozzle (generally designated <NUM>) suitable for use in a high volume spray coating process of the present invention. It will be appreciated that in use the nozzle <NUM> would normally be inverted relative to the position illustrated in <FIG> and <FIG> so that capsules emerging from the nozzle would be directed downwardly on to a substrate, as illustrated in <FIG>.

As will readily be apparent to those familiar with spray nozzle technology, the nozzle <NUM> shown in <FIG> and <FIG> operates in substantially the same manner as the nozzle <NUM> shown in <FIG> but the nozzle <NUM> has the following structural differences:.

<FIG> shows four dimensions which have been found important in achieving good spray coating results from the nozzle <NUM> shown in <FIG> and <FIG>, these four dimensions being (A) the radius of the central orifice <NUM>; (B) the radial distance between the outer edge of the central orifice <NUM> and the inner edge of the annular orifice 706D; (C) the radial width of the annular orifice 706D; and (D) the axial distance between the orifices <NUM> and <NUM>.

The quality of capsules coatings is assessed in terms of their reproducibility granularity, mean coating weight, uniformity and defect density; defect density is quantified by the number of non-switching capsules per unit display area in a standard display structure, which for present purposes is defined as a backplane bearing, in order, a <NUM> layer of lamination adhesive, a <NUM> capsule layer and a front substrate comprising an ITO layer on <NUM> polyethylene terephthalate film. The first factor to be considered in achieving good spray coatings is capsule and gas flow rates and pressures. It has been found empirically that capsule spraying is best achieved using a high-volume, low-pressure ("HVLP") nozzle; a variety of standard nozzle designs known in the art may be used, but the preferred design is that shown in <FIG> and <FIG>. Preferably, the ratio of atomization air outlet cross-section to capsule dispersion outlet cross section is not greater than about <NUM>, and preferably between about <NUM> and about <NUM>. The capsule dispersion orifice diameter (twice A in <FIG>) is preferably in the range of about <NUM>-<NUM>. The capsule dispersion may contain capsules in a weight fraction preferably between about <NUM> and about <NUM> weight per cent; this dispersion may optionally contain <NUM>-butanol at a concentration of up to about <NUM> weight per cent and a surfactant, such as Triton X-<NUM> at a concentration of up to about <NUM> weight per cent.

A wide range of capsule dispersion feed rates and atomization air feed rates can be used in the spray coating process of the present invention. Typically, the capsule dispersion feed rate, MF, is not less than about <NUM>/min and not greater than about <NUM>/min, the optimum being determined mainly on the basis of an appropriate residence time in the atomization zone, that is to say the region in which the capsule dispersion column emerging from the first orifice breaks into sheets of fluid, which subsequently break into ligaments and finally droplets. Desirably, the droplet size distribution is such that the mean capsule count per droplet is less than about <NUM>, and the standard deviation is less than about <NUM>, capsules per droplet. The atomization air feed rate is set on the basis of a critical air velocity, v*, measured at the second orifice, and is typically of the order of about <NUM>/sec. In the preferred process, a total air feed rate, MA, (including atomization air and shaping air) of approximately <NUM> to <NUM>/min is employed in the absence of shaping air, and up to <NUM>/min with shaping air.

Empirically, it has been found that the operating window for HVLP atomization in terms of MA/MF versus MF, has the form shown in <FIG>, although the numerical values involved will vary with the particular nozzle design used. The unshaded region of the graph of <FIG> represents the desirable operating window. The shaded regions represent defect regions which result in undesirable spray patterns such as excessive fluid velocity ("jetting"), highly irregular and transient spray structure, and coarse droplet distribution.

In the spray coating process of the present invention, the air feed rate and nozzle-to-substrate distance should be carefully controlled to avoid capsule damage. In general, a nozzle-to-substrate distance of <NUM> to <NUM> is optimal, and this distance should be adjusted approximately inversely to atomization air velocity squared.

It has also been found that the quality and uniformity of the sprayed capsule coating can be strongly influenced by pretreatment of the substrate and by additives added to the capsule dispersion. Useful pretreatments and additives include but are not limited to:.

A capsule dispersion was sprayed with an HVLP nozzle using inlet atomization air at a pressure of <NUM> psig (about <NUM> MNw m-<NUM>) measured at the nozzle inlet, with a gravity feed of the capsule dispersion. Depending on the dispersion viscosity, the mass flow rate of the dispersion was approximately <NUM> to <NUM>/min. The spray was directed vertically downward and deposition took place at near normal incidence on to a horizontal substrate so as to avoid inclined plane flow after deposition. The nozzle-to-substrate distance was <NUM> to <NUM>, but may be lower or higher. Capsule spraying took plane across a thin film transistor backplane in one or more passes to achieve a target mean coating weight given by the following relationship: <MAT> where Θ is the mean coating weight (in g/m<NUM>), MF is the dispersion mass feed rate (in g/min), N is the number of passes over the substrate, η is the spray transfer efficiency at each pass (which should be at least <NUM>%), W is the substrate width (in meters), v is the actuation velocity (in m/min). In one process of the invention, the target mean coat weight Θ = <NUM> -d, MF = <NUM>/min, η ~ <NUM> - <NUM>%, and W = <NUM>. In this process, multiple coating passes could be used so long as the total residence time of a given substrate underneath the nozzle did not exceed about <NUM> or <NUM> seconds; longer coating times left the thin sub-layers ineffective by evaporation.

As already mentioned, the spray coating process of the invention may include the use of a masking material covering part of the substrate so that, after removal of the masking material, capsules remain only on those portions of the substrate where the masking material was not present. The masking material used to cover part of the substrate should not be porous, or at least should have low enough porosity to ensure that capsule deposition on to the masked areas of the substrate does not occur. The masking material should not significantly absorb the liquid (usually aqueous) in which the capsules are dispersed, and should be placed close enough to the surface of the substrate that lateral draft of capsules beneath the masking material from the unmasked regions of the substrate into the masked areas does not occur. After the capsules have been deposited on the substrate, the capsules may be dried (or otherwise treated to form a coherent layer, for example by exposure to radiation) with the masking material still in position, or the masking material may first be removed and then the capsules dried or otherwise treated. In either case, the physical properties of the masking material and the capsule dispersion should be chosen so that, during the removal of the masking material, capsules are not dragged into previously masked areas of the substrate, nor are capsules removed from unmasked areas (for example, by irregular tearing of a coherent dried layer of capsules.

The masking film may comprise an adhesive pre-laminated on to the surface on to which the capsules are to be deposited, and a release film exposed to the spray. After capsule deposition, the release film is removed, followed by additional processing. The resultant spray-printed film may then be laminated to a backplane, which may be either transparent or opaque.

<FIG> is a top plan view of a first electrophoretic produced by a masked spray coating process of the invention. The backplane is made transparent to allow visibility through the display outside of the areas (circles in <FIG>) on which the capsules have been deposited. Such a backplane can generate a patterned image with as many individual optical states as the electrophoretic medium is capable of generating. In the display shown in <FIG>, the capsules contain a white and a magenta pigment, so that all possible states of the display are a combination of magenta and/or white, including the extreme magenta and white optical states.

As already mentioned, the masked spray coating process of the invention may comprise more than one coating step and thus allow deposition of two or more different electrophoretic media on a single substrate. <FIG> is a top plan view of a display produced in this manner. The display shown in <FIG> is produced by applying a first masking material to a front plane electrode, and then spray coating electrophoretic capsules containing blue and white pigments over the first masking material. After drying the capsules and removing the first masking material, a second masking material is applied to the front electrode, and electrophoretic capsules containing yellow and white pigments are spray coated on to the electrode. The second masking material is then removed and the front electrode and overlying electrophoretic layer laminated to a backplane. The display shown in <FIG> has two primary optical states, namely a uniform color determined by the common pigment (in this case, white) and a second patterned (blue/yellow) state as illustrated in <FIG>.

The spray coating process of the present invention overcomes the limitation of prior art coating processes such as slot coating and thus provides the ability to do patch coating and coating of three dimensional objects. The spray coating process is also less susceptible to streaking due to clogging of the die in slot coating processes, and thus can offer enhanced yields. The spray coating process also avoids the need for lamination adhesive layers between the electrodes of a display, thus permitting a higher electric field across the electrophoretic layer for a given operating voltage and thus enabling higher white state brightness and higher contrast ratio, as well as the potential for reduced blooming and enhanced microcontrast as a result of the electrophoretic capsules being in direct contact with the backplane.

Printed encapsulated electrophoretic displays are desirable in applications such as window screens, wall panels, or other architectural elements in which either a low information density display or artistic relief is desired with minimal or no active matrix driving. Instead, the interfaces between switching and non-switching, or between two regions of differing electrophoretic medium which switch in a qualitatively different manner, may be pre-patterned into the display. The masked spray coating process of the present invention provides a way of achieving these aims without compromising the mechanical integrity of the deposited capsules.

As already mentioned, this disclosure provides a process for forming a monolayer of capsules on a substrate, the process comprising depositing a solution of a water swellable polymer on the substrate; and thereafter depositing a quantity of the capsules sufficient to form a monolayer of capsules on to the substrate, and allowing the capsules to arrange themselves into a monolayer on the substrate.

In this process, it is important to control the quantity of capsules deposited on each unit area of the substrate; this quantity should be controlled so that the capsules can rearrange on the substrate into a tightly packed monolayer. The rearrangement of capsules may take place immediately after the deposition of the capsules on the substrate but, perhaps more commonly, may take place after the capsule layer is dried or otherwise treated to form a coherent layer of capsules on the substrate. As previously noted, it is desirable that the deposition of the capsules be effected by a process such as spray coating (or alternatively curtain coating or deposition of capsules from nozzles or similar processes) which do not require contact of a coating head or bar with the capsule layer. With the swellable polymer reducing adhesion of the capsules to the substrate, a coating head or bar will tend to drag the capsules along with it, thus resulting in a very sparse capsule coating on the substrate, too sparse to enable a well packed monolayer of capsules to be formed. If coating is attempted without the swellable polymer pre-treatment, the capsules stick to the substrate as they are deposited by a coating head or bar, but the adhesion of the capsules to the substrate is so great that capillary forces are insufficient to allow for capsule rearrangement and the formation of a well packed monolayer of capsules.

<FIG> of the accompanying drawings illustrate successive stages of an experimental process of the present invention in which a microscope slide was treated with egg albumen and then had capsules deposited thereon from a pipette. It will be seen from these Figures that the originally scattered capsules deposited from the pipette were gradually drawn by capillary forces into a closely packed monolayer covering about three-fourths of the area of the slide shown in the Figures. When a similar experiment was attempted with bar coating on an albumin-treated slide, the capsules simply clung to the coating bar and virtually no capsules were left behind on the slide. When covering much larger areas than a microscope slide, the albumin coating process of the present invention renders it possible to generate large area of closely packed monolayers of capsules.

From the foregoing, it will be seen that the swellable polymer coating process of the present invention provides a process for generating large quantities of closely packed capsule monolayer coatings using conventional equipment and materials suitable for mass production. The process should produce coatings essentially free from grain, especially if the capsules are applied by spray coating, as the spray should randomize the size distribution of capsules over the coating area. The swellable polymer coating process may be especially useful in providing coatings for use in variable transmission windows, where multilayers of coatings and coating defects (uncoated areas) are highly visible and adversely affect the quality of the windows.

As already mentioned, the overcoat layer process of this disclosure comprises:
providing a backplane comprising at least one electrode; coating the backplane with a layer of an electro-optic material; depositing a layer of a substantially solvent-free polymerizable liquid material over the layer of electro-optic material; contacting the polymerizable liquid material with at least one light-transmissive electrically-conductive layer; and exposing the polymerizable liquid material to conditions effective to cause polymerization of the material, thereby adhering the at least one light-transmissive electrically-conductive layer to the layer of electro-optic material.

The advantages of the overcoat layer process of the present invention may be seen by comparing <FIG> shows a schematic cross-section through a prior art color display (generally designated <NUM>) comprising, in order, a backplane <NUM>, a first (relatively thin) adhesive layer <NUM>, a monochrome electro-optic layer <NUM>, a second adhesive layer <NUM> substantially thicker than the first adhesive layer <NUM>, a front electrode layer <NUM>, a front substrate <NUM> and a color filter array <NUM>, which may be printed directly on to the front substrate <NUM>. This structure may be formed using a double release film in the manner described above. Note that in the display <NUM> the CFA <NUM> is separated from the electro-optic layer <NUM> by the thicknesses of the front substrate <NUM> and the second adhesive layer <NUM>, which together are typically about <NUM> thick. (The front electrode layer <NUM> is typically less than <NUM> thick and thus for practical purposes its thickness may be ignored.

<FIG> is a schematic cross-section, similar to that of <FIG>, but taken through a display (generally designated <NUM>) produced by the overcoat layer process of the present invention. The backplane <NUM>, electro-optic layer <NUM>, front electrode layer <NUM>, front substrate <NUM> and CFA <NUM> are all similar to the corresponding layers in the prior art display <NUM> shown in <FIG>. However, in <FIG> the electro-optic layer <NUM> is coated directly on to the backplane <NUM> so that the first adhesive layer <NUM> present in the display <NUM> is eliminated. Furthermore, the second adhesive layer <NUM> in display <NUM> is replaced in display <NUM> by a much thinner adhesive layer <NUM> formed by polymerization of a solvent-free polymerizable liquid material. The adhesive layer <NUM> will typically have a thickness of only about <NUM>, thus reducing the spacing between the CFA <NUM> and the electro-optic layer <NUM> to about <NUM>, a <NUM> per cent reduction from the spacing in display <NUM>, with a corresponding reduction in both illumination and viewing parallax, thus providing a wider viewing angle and higher color saturation. In addition, the elimination from display <NUM> of the first adhesive layer <NUM> in display <NUM> increases the voltage drop across the electro-optic layer and reduces blooming. The overcoat layer process of the present invention may also be applied to black-and-white displays having a structure similar to that of display <NUM> but lacking the CFA <NUM>.

As already indicated, the present invention may also be applied to inherent color displays, as illustrated in <FIG> is a schematic cross-section through a prior art display (generally designated <NUM>), which is generally similar to the display <NUM> shown in <FIG> except that the electro-optic layer <NUM> is an inherent color electro-optic layer which is capable of displaying a range of colors at every pixel of the display, as described, for example in <CIT>, and the color filter array is omitted. <FIG> shows a display <NUM> produced by the overcoat layer process of the present invention. As with the display <NUM> described above, in the display <NUM> the first adhesive layer <NUM> is omitted and the second adhesive layer <NUM> is replaced with a much thinner adhesive layer <NUM> formed by polymerization of a solvent-free polymerizable liquid material. As with the display <NUM> described above, eliminating the first adhesive layer <NUM> allows more of the electric field applied to the display to reside within the electro-optic layer <NUM>, resulting in a brighter white state and higher contrast ratio. In addition, micro contrast will be greatly improved because blooming effects associated with the first adhesive will be eliminated, thereby increasing color gamut and image sharpness.

The overcoat layer process of the present invention may include various optional features. When the electro-optic layer is to be an encapsulated electrophoretic layer, the capsule slurry used to apply the capsules to the backplane may include surfactants, such as Triton X-<NUM> or butanol, to improve wetting of the backplane. Prior to coating of the electro-optic layer, the backplane may be pre-coated with surfactants, such as Triton X-<NUM> or butanol, or with a polyurethane latex. Alternatively or in addition, the backplane may be pre-treated with plasma (including atmospheric plasma) or corona discharge treatment. Such treatment may be effected at various power settings and with various gases, including but not limited to oxygen, nitrogen etc. As previously noted, in general it is preferred that the electro-optic layer in the overcoat layer process be applied by spray coating, including electrostatic spray coating, but other application techniques, such as slot die coating, blade coating and roll coating (including flexo and gravure techniques) may also be used. When the electro-optic layer is to be an encapsulated electrophoretic layer, the capsules are desirably in the form of a slurry containing a polymeric binder, for example a polyurethane latex.

An overcoat layer process of the present invention was carried out by depositing capsules of an electrophoretic medium on to a backplane, overcoating the capsules with a solvent-free polymerizable liquid material and adhering a front electrode layer/front substrate (in the form of a poly(ethylene terephthalate) film coated on one surface with ITO) to the electrophoretic medium by means of the polymerizable liquid material.

The spraying of the capsules on to an active matrix backplane was effected using the spray coating process of the present invention and substantially as in Example <NUM> above using an HVLP nozzle at a pressure of <NUM> psig (about <NUM> MNw m-<NUM>) measured at the nozzle inlet, with a gravity feed of the capsule dispersion at a mass flow rate of <NUM> to <NUM>/min. The spray was directed vertically downward and deposition took place at near normal incidence on to a horizontal substrate so as to avoid inclined plane flow after deposition. The nozzle-to-substrate distance was <NUM> to <NUM>. The target coating weight was <NUM>/m<NUM>. Multiple spray heads and higher dilution coating slurries may contribute to increased coating uniformity.

The polymerizable liquid material used was formulated as follows (the various Sartomer resins used are available from Sartomer Americas, Inc. , Overland Park KS):.

These components were combined and placed on a roll mill for at least eight hours to ensure thorough mixing.

The displays were assembled as follows. A metal pan was covered with cardboard to provide cushioning, and a sheet of plastic release sheet was placed on top of the cardboard. The capsule-coated backplane was placed on this pan, and polyimide tape was used to cover the contacts on the backplane. A PET/ITO film was cut to the size of the backplane, placed over the capsule-coated backplane, and taped in place with polyimide tape. A sheet of metalized release sheet was placed on top of the stack, and the whole assembly moved to a laminator, with the roller closed just barely on the glass of the backplane. The laminator was set to 20psi and 25ft/min (<NUM>/min) to assure an ultraviolet-cured coating of the desired thickness. The PET/ITO was lifted up, allowing a bead of the polymerizable liquid mixture to be placed as close as possible to one edge of the PET/ITO film; the film was lifted for as long as possible while the roller moves the polymerizable liquid mixture to the opposed edge of the backplane. Finally, the metalized release film was removed and the polymerizable liquid mixture cured. The tape used to cover the contacts on the backplane was removed, and use carbon tape (or silver paste) applied to make electrical contact with the ITO layer. The display thus produced was conditioned at <NUM> and <NUM>% relative humidity for <NUM> days, then edge sealed with a hydrophobic UV curable polymer.

Claim 1:
A process for producing a sub-assembly for use in an electro-optic display, the process comprising:
providing a backplane (<NUM>) comprising at least one electrode located in a first area (<NUM>) of the backplane (<NUM>);
covering a second area (<NUM>) of the backplane (<NUM>) spaced from the electrode with a masking layer (<NUM>);
coating the backplane (<NUM>) having the masking layer (<NUM>) thereon with a layer of an electro-optic material (<NUM>), wherein the electro-optic material (<NUM>) comprises an electrophoretic material; and
removing the masking layer (<NUM>), and the electro-optic material (<NUM>) thereon, from the backplane (<NUM>), thereby producing a sub-assembly comprising the backplane (<NUM>) having its first area (<NUM>) covered by the layer of electro-optic material (<NUM>) but its second area (<NUM>) free from the layer of electro-optic material (<NUM>).