Patent Description:
The present invention further pertains to a deposition device comprising the donor plate.

The present invention still further pertains to a method of depositing using a donor plate.

Deposition methods are known, wherein a deposition substance to be deposited is ejected from recesses in a surface of a donor plate onto a surface of a target. <CIT> for example discloses a tracks pattern production apparatus that transfers a filler contained in trenches of a donor substrate to a receptor object. A scanning laser is proposed therein to induce a thermal transfer of the filler. A lateral position where the transferred filler is deposited on the receptor object does not only depend on a lateral position of the trench from which it originates, but also depends on a transfer direction in which the filler leaves the trench upon its ejection. In practice it is sometimes difficult to accurately control the transfer direction, so that lateral deviations occur in the deposition location. Accordingly, there is a need to provide means that enable a more accurate control of the deposition location.

Other deposition methods are suggested as illustrated in <FIG>. Instead of using a scanning laser, resistive heating is applied to induce heat for causing ejection of the filler, e.g. a functional ink. In the example shown in <FIG>, an anode and a cathode are provided as busbars that are embedded in a wafer, serving as a carrier and the resistive heater is provided as a resistive layer with respective resistive layer sections that extend between a pair of busbars of mutually opposite polarity. The filler is provided in cavities in an insulating layer deposited on a side of the carrier provided with the resistive layer. Upon providing electric energy the resistive layer sections. For further information, reference is made to the following documents <CIT>, <CIT>, <CIT> and <CIT>.

<CIT> pertains to fabrication of organic electronic circuits by contact printing techniques. Therewith a printing stamp is used with a hydrophobic patterned printing side that is loaded with a printing medium containing an organic conductive polymer. The stamp is brought into contact with a hydrophilic substrate. Therewith a patterned layer including the organic polymer is formed on the substrate. The method can be operated continuously through selection of suitable geometries for the printing stamp and the substrate.

<CIT> pertains to a thermal transfer element for forming a multilayer device. The transfer element may include a substrate and a multicomponent transfer unit that, when transferred to a receptor, is configured and arranged to form a first operational layer and a second operational layer of a multilayer device. In at least some instances, the thermal transfer element also includes a light-to-heat conversion (LTHC) layer that can convert light energy to heat energy to transfer the multicomponent transfer unit. Transferring the multicomponent transfer unit to the receptor may include contacting a receptor with a thermal transfer element having a substrate and a multicomponent transfer unit. Then, the thermal transfer element is selectively heated to transfer the multicomponent transfer unit to the receptor according to a pattern to form at least first and second operational layers of a device. Also an embodiment with resistive heating elements are described.

<CIT> discloses a recording head for a thermal jet. An partition member of the same material as an electrode is securely fitted between resistance heating elements.

<CIT> pertains to a method for manufacturing a light-emitting device. A first supporting substrate side of an evaporation donor substrate is irradiated with light. The irradiation light is reflected in a region where the reflective layer is formed but is transmitted through the opening of the reflective layer to be absorbed in the first region of the light absorption layer which overlaps with the opening. The absorbed light is converted into heat energy, whereby a part of the material layer which is in contact with the light absorption layer in the region overlapping with the opening is heated so that the evaporation material is evaporated onto the first electrode layer.

According to a first aspect a donor plate for deposition of a deposition substance on a target, is provided as claimed in claim <NUM>.

The donor plate comprises a flexible substrate, which at a first main surface subsequently has an electrode layer, a first electrically insulating layer, a resistive heater layer, a second electrically insulating layer and a patterned layer provided with one or more recesses for holding deposition substance to be deposited on the target.

The electrode layer comprises a first and a second electrode of a complementary shape and that are electrically insulated from each other, and the resistive heater layer is electrically connected to each of a contact surface of the first electrode and a contact surface of the second electrode via at least one respective slit in the first electrically insulating layer.

Upon supplying electric energy to the resistive heater layer the heat developed therein causes the flexible substrate to deform so that the patterned layer moves towards the target. Consequently a gap between the patterned layer and the target, and therewith deviations in the deposition location due to deviations in the transfer direction are reduced.

The deposition substance to be deposited is a viscous material. The viscosity is typically at least <NUM> Pa. s (to avoid undesired deformation). In some cases the viscosity is in the order of <NUM> Pa. Exemplary deposition substances are an electrically conductive material, such as an electroconductive polymer, a metallized polymer, a solder paste, conductive adhesive, an electrically insulating material, such as an electrically insulating polymer, a semi-conductive material, such as a semi-conductive polymer. Alternatively, or additionally a deposition substance, whether electrically conductive, semi-conductive or insulating may serve as a thermal insulator or instead as a thermal conductor. substance, whether electrically conductive, semi-conductive or insulating may serve as a thermal insulator or instead as a thermal conductor.

Additional elements, other than those mentioned above, may be present. For example, a heat spreader layer may be provided between the second electrically insulating layer and the patterned layer in areas with a recession to contribute to a further improvement of a heat flux towards the deposition substance therein. In exemplary embodiments the patterned layer is of a thermally insulating material. The recesses form interruptions therein to enable an efficient heat flow from the resistive heater layer towards the deposition substance.

In an embodiment, at each position of the resistive heater layer a smallest distance between the at least one slit of the first electrode and the least one slit of the second electrode is at most one tenth of the square root of an effective surface area of the resistive heater layer. The effective surface area of the resistive heater layer referred to herein is the area of the resistive heater layer being electrically connected with both electrodes. With this measure it is achieved that electric power for heating the resistive heater layer can be supplied with a comparatively low supply voltage. The lower supply voltage enables a thinner implementation of the first electrically insulating layer. The lower supply voltage furthermore allows for a reduction of the electrode separation. As a result the electrode layer can serve as an efficient and substantially homogeneous heat sink. Therewith the donor plate can rapidly cool down to restore its original shape. As a result, the donor plate can retract away from the target surface, before deposited deposition substance has an opportunity to solidify and adhere to the donor plate.

In examples of this embodiment, the first and the second electrode are comb-shaped, having respective sets of comb fingers wherein the comb fingers of the first electrode and the comb fingers of the second electrode are interleaved. At least one slit of the first electrode comprises a respective slit for each comb finger of the first electrode and the at least one slit of the second electrode comprises a respective slit for each comb finger of the second electrode. The respective slits in the first electrically insulating layer extend in a longitudinal direction of the comb fingers over their respective contact surface. Whereas typically, the distance l between the slits is constant and the thickness d of the resistive heater layer is uniform, this is not essential. Variations therein are allowable, provided that the product of the square of the distance <NUM> and the sheet resistance is constant.

In other examples, the first and the second electrode extend alongside each other according to a spiral trajectory. The at least a first slit longitudinally extends over the contact surface of the first electrode and the at least a second slit longitudinally extends over the contact surface of the second electrode.

Some embodiments of the donor plate, additionally comprise respective, independently controllable sets of one or more resistive heating elements arranged between the second electrically insulating layer and the patterned layer in respective zones defined by respective ones of the recesses. The independently controllable sets of one or more resistive heating elements render it possible to independently control the ejection of deposition substance from the recesses. Therewith a point in time of ejection of the deposition substance from the recesses can be independently selected from the point in time at which the resistive heater layer is powered. Therewith it is possible to control a speed with which the ejected deposition substance arrives at the target. In examples thereof, at least one independently controllable set of one or more resistive heating elements comprises at least two independently controllable resistive heating elements. Through independently controlling the at least two independently controllable resistive heating elements, a distribution of forces exerted on the deposition substance to be ejected from the recess can be adapted to the morphology of the target surface. Also this enables an additional way of controlling of a shape in which the deposition substance will solidify on the target surface.

According to a second aspect a deposition device is provided as claimed in claim <NUM>. The deposition device, comprising the donor plate according to one of the embodiments or specific examples thereof specified above, and further comprises a plate carrier. The donor plate is laterally attached at a second main surface opposite its first main surface to a first plate carrier surface of the plate carrier. The plate carrier serves as a holder for the donor plate. As the flexible substrate is attached to the donor plate carrier only at its periphery, the donor plate is free to deform as a result of thermal expansion within the constraints defined by the attachment at its periphery. In an example thereof, the plate carrier is mounted to a reference frame at a first side and at a second side opposite the first side is slidably coupled to the reference frame with a linear slide to allow the plate carrier to expand in a direction along an axis from said first side to said second side. Although the plate carrier is not directly heated, it may be subject to temperature variations due to heat induced in the donor plate. In this way deformation of the plate carrier due to such temperature variations can be avoided. If a very high deposition accuracy is required it may be contemplated to adapt the design of the pattern for compensation of a shift of the pattern elements in the lateral direction due to said sliding. The expected shift, and therewith the proper adaptation can be computed relatively easily for example by a simulation. Alternatively or additionally it may be contemplated to measure the locations of deposited material at the target and from these observations to design an improved pattern for the donor plate.

In an embodiment of the deposition device the donor plate is fixed to the plate carrier with a round going seal. In an example thereof the plate carrier has one or more channels that extend through the plate carrier that are configured to be coupled to a pressure control unit. The donor plate may be attached to the plate carrier in a pre-tensioned manner, so that in a standby mode of the deposition device, preceding a deposition mode, the donor plate is held flat against the plate carrier surface. This implies however that a relatively high supply power is necessary to sufficiently deform the donor plate as the pretension must be compensated. In this embodiment it is not necessary that the donor plate is attached with pretension. In the standby mode the pressure control unit is configured to apply a vacuum in the middle of the donor plate, so that it is firmly held flat against the plate carrier. During plate deformation, the vacuum seal should be broken automatically. This can be achieved in that the deformation of the plate results in a temporary opening therein that allows air to pass through, so as to cancel the vacuum.

In an embodiment of the deposition device one or more spacers are provided at a free surface of the patterned layer. The spacers contribute in maintaining a stable reference distance between the donor plate and the target.

In an embodiment of the deposition device, the donor plate in a radially outward direction has a central section, a resistively heatable intermediary section and a peripheral section. Therein the central section comprises a section of the flexible substrate, with the electrode layer, the first electrically insulating layer, the resistive heater layer, the second electrically insulating layer and the patterned layer. The intermediate section surrounds the central section and the donor plate is attached with its peripheral section to the plate carrier. By resistively heating the intermediary section, the central section of the donor plate can be translated towards the target without substantial deformation. In examples of this embodiment the intermediary section has a thermal expansion coefficient greater than that of the central section. This can be achieved in that the substrate is locally modified.

Therewith a substantial deformation of the intermediary section can be achieved.

In an example, the intermediary section of a sectioned plate as described above may comprise a plurality of heating layers. Therewith a relatively large heat flux can be induced to achieve a substantial deformation of the intermediate section.

In an example, the central section of a sectioned plate as described above comprises a further resistive heater layer wherein the resistive heater layer and the further resistive heater layer are arranged at opposite sides of a virtual central plane of the central section. In this example, one of the resistive heater layers that is arranged closer towards the patterned layer is heated to induce an ejection of the deposition substance. The other one of the resistive heater layers that is closer to the plate carrier is heated to minimize a temperature gradient in a thickness direction of the central section, so that a deformation of the central section is mitigated.

In an example of a sectioned plate as described above, a thickness of the central section increases in a radially outward direction. As a result, also the thermal equilibration time increases in the radially outward direction. Consequently the thermal expansion will be relatively high for radially outward positions of the donor plate as compared to more radially inward positions. Therewith a bending of the donor plate can be compensated to keep the donor plate flat in the printing area. A radially outward increasing thickness may be provided for example in that the thickness of the flexible substrate increases in that direction, or in that the flexible substrate is provided with a coating at the side facing the plate carrier with such a thickness profile.

According to a third aspect a deposition method is provided as claimed in claim <NUM>. The method of depositing specified therein uses a donor plate comprising a flexible substrate, which at a first main surface subsequently has an electrode layer, a first electrically insulating layer, a resistive heater layer, a second electrically insulating layer and a patterned layer provided with one or more recesses for holding a deposition substance to be deposited on a target, wherein the electrode layer comprises a first and a second electrode of a complementary shape and being electrically insulated from each other, and wherein the resistive heater layer is electrically connected to each of the first electrode and the second electrode via at least one respective slit in the first electrically insulating layer.

A method according to the third aspect as claimed in claim <NUM> comprises:.

As the donor plate moves to the target, when it is heated, and therewith optionally contacts the target, a printing gap is reduced. Therewith a printing accuracy is improved.

It is noted that the step of uniformly heating the donor plate may at the same time sufficiently heat the deposition substance to result in an ejection thereof.

In an embodiment of the method according to the third aspect, the donor plate has respective, independently controllable sets of one or more resistive heating elements arranged between the second electrically insulating layer and the patterned layer in respective zones defined by respective ones of the recesses, and wherein the method further comprises independently controlling the step of ejecting by providing electric energy to said respective, independently controllable sets of one or more resistive heating elements. In this embodiment, ejection of the deposition substance can be controlled to take place in a particular state of the donor plate therewith rendering it possible to control the velocity with which a deposition is propelled towards the target.

Steps of the method may be carried out by a programmable processor for example to control a providing of electrical energy to the resistive heater layer and/or to independently controllable sets of one or more resistive heating elements. To that end, a computer program product may be provided that comprises a computer program, which when executed by a programmable processor causes the programmable processor to carry out such steps of the method.

These and other aspects are described in more detail with reference to the drawing.

Like reference symbols in the various drawings indicate like elements unless otherwise indicated.

<FIG> schematically shows an embodiment of a donor plate <NUM> for deposition of a deposition substance <NUM> on a target <NUM>. The donor plate comprises a flexible substrate <NUM>, e.g. a silicon substrate, which at a first main surface <NUM> subsequently has an electrode layer <NUM>, a first electrically insulating layer <NUM>, a resistive heater layer <NUM>, a second electrically insulating layer <NUM> and a patterned layer <NUM> provided with one or more recesses <NUM> for holding deposition substance <NUM> to be deposited on the target. The patterned layer <NUM> may comprise a thermal insulator layer <NUM> to reduce a heat flux outside the areas defined by the recesses. The electrode layer <NUM> comprises a first and a second electrode <NUM>, <NUM> which are of a complementary shape and which are electrically insulated from each other by a gap <NUM>. The gap may be provided as free space or may be filled with an insulating material. For example, the material of the carrier. In an example, a width Wg of the gap is less than <NUM> micron, e.g. less than <NUM> micron. The resistive heater layer <NUM> is electrically connected to each of a contact surface of the first electrode <NUM> and a contact surface of the second electrode <NUM> via at least one respective slit <NUM>, <NUM> in the first electrically insulating layer. In the example shown, the slits have a width Ws of less than <NUM> micron.

<FIG> shows a top view of the plate as seen in a direction away from the target surface <NUM>.

In the embodiment of <FIG> the first and the second electrode <NUM>, <NUM> are comb-shaped. Each of the electrodes has a respective sets of comb fingers <NUM>, <NUM>. As can be seen in <FIG>, the comb fingers <NUM> of the first electrode <NUM> and the comb fingers <NUM> of the second electrode <NUM> are interleaved. The at least one slit <NUM> of the first electrode <NUM> comprises a respective slit for each comb finger <NUM> of the first electrode <NUM> and the at least one slit <NUM> of the second electrode <NUM> comprises a respective slit for each comb finger <NUM> of the second electrode <NUM>. The slits in the first electrically insulating layer <NUM> extend in a longitudinal direction of the comb fingers over their respective contact surface <NUM>, <NUM>. In the example shown in <FIG>, the distance De between the slits is smaller than about <NUM>.

In the example shown in <FIG> and <FIG>, at each position of the resistive heater layer <NUM> the smallest distance De between the at least one slit <NUM> of the first electrode <NUM> and the least one slit <NUM> of the second electrode <NUM> is at most one tenth of the square root of an effective surface area Aeff of the resistive heater layer <NUM>. The effective surface area Aeff of the resistive heater layer <NUM> referred to herein is the area of the resistive heater layer that is electrically connected with both electrodes. In the example shown, the effective surface area Aeff is equal to the product of a length L and a width W of the resistive heater layer <NUM> that is in electric contact with the electrodes <NUM>, <NUM>.

By way of example, the values for the length L and the width W may both be <NUM>, and therewith the distance De between the slits is less than one tenth of the square root of the effective surface area Aeff of the resistive heater layer.

In operation an electric voltage is applied between the electrodes <NUM>, <NUM>, to resistively heat the deposition substance <NUM> provided in the recesses <NUM> in the patterned layer <NUM>. <FIG> shows a heatflux as measured as a function of a position in a direction from left to right along a surface of the resistive heater layer <NUM> facing the patterned layer <NUM> As shown in <FIG>, the arrangement of the resistive heater layer of <FIG> and <FIG> provides for a very homogeneous heat flow, so that the deposition substance is ejected with a uniform ejection velocity within a recess <NUM>. Only minor variations occur. at the location of the slit <NUM> small dips occur in the heatflux towards the patterned layer. This is due to the fact that part of the heat flows towards the electrodes <NUM>, <NUM> as the electrical connection formed therein between the electrodes and the resistive heater layer <NUM> also provides a thermal connection. It can be seen however in <FIG> that this effect is minimal due to the small width of the slits. Also, local spikes in the heat flux towards patterned layer can be observed which are due to a lower heat sink effect in the gaps between neighboring electrodes. the electrodes <NUM>, <NUM> typically being of a metal generally have a relatively high conductivity whereas electrically insulating materials, e.g. as SiO2 or SiN generally have a lower thermally conductivity. As can be seen in <FIG> also the spikes are modest, due to the relatively small width Wg of the gaps between the electrodes. As a further measure, a heat spreader layer <NUM>, being of a material with a high thermal conductivity is provided at a bottom of the recesses <NUM> that further contributes to a uniform distribution of the heatflux towards the patterned layer <NUM>. <FIG> shows that the magnitude of the heatflux is slightly above the threshold heatflux The required to eject the deposition substance <NUM> out of the recesses.

With reference to <FIG>, it is noted that it is not essential that the distance between mutually subsequent slits is the same for the full area of the plate. For example, a first pair of subsequent slits may have a distance l<NUM> and a second pair of subsequent slits may have a different distance l<NUM>, such that: <MAT>.

Therein <MAT> and <MAT> are the sheet resistance of a portion of the resistive heater layer <NUM> between the first pair of subsequent slits and between the second pair of subsequent slits respectively. The portions may have a mutually different sheet resistance by an appropriate selection of the resistive material for the resistive heater layer portions or by an appropriate selection of their thicknesses.

<FIG> schematically shows three operational stages of a deposition device. Referring for example to <FIG>, which shows the deposition device in an initial operational state, the deposition device comprises a donor plate <NUM> and a plate carrier <NUM>. The donor plate <NUM> is laterally attached at a second main surface <NUM> opposite its first main surface <NUM> to a first plate carrier surface <NUM> of the plate carrier <NUM>.

The plate carrier <NUM> is mounted to a reference frame REF at a first side <NUM>. At a second side <NUM> opposite the first side it is slidably coupled to the reference frame to allow the plate carrier <NUM> to expand in a direction along an axis from the first side to the second side.

As is further shown in <FIG>, the donor plate <NUM> is fixed to the plate carrier <NUM> with a round going seal <NUM> and the plate carrier has one or more channels <NUM> extending through the plate carrier, which channels <NUM> are configured to be coupled to a pressure control unit.

The deposition device shown in this example comprises one or more spacers <NUM> at a free surface <NUM> of the patterned layer <NUM>.

A deposition method using the deposition device is now described for the three operational stages shown in <FIG>. In the first stage S1 shown in <FIG>, the donor plate <NUM> is positioned with its patterned layer <NUM> in a non-contacting manner in front of the target <NUM>. It can be seen that the spacers <NUM> therewith maintain a predetermined distance of the patterned layer <NUM> to the target surface. Alternatively a servo system may be used to achieve a proper positioning. In the first stage the donor plate typically has a temperature equal to roomtemperature, e.g. about <NUM>.

As shown in <FIG>, in a subsequent step S2, an electric voltage is applied to the resistive heater layer <NUM> of the donor plate to therewith heat the donor plate in a substantially uniform manner. Therewith, the first main surface <NUM>, which is closer to the patterned surface is heated more rapidly than the second main surface <NUM>, facing the plate carrier <NUM> a substantial temperature difference is caused. For example, while the second main surface <NUM> still has a temperature close to room temperature, the first main surface <NUM> may rapidly achieve, for example within <NUM> to <NUM> microsecond, a substantially higher temperature in the order of magnitude of a few hundred degrees, e.g. <NUM>. As a result the donor plate is deformed over a width Wd until the patterned layer <NUM> contacts the target. At that point in time, the deposition substance is ejected in step S3 to be deposited from the recesses <NUM> onto the target. As in this stage the patterned layer <NUM> contacts the target, the traveling distance for the deposition substance is substantially zero, so that lateral deviations in the deposition location are minimized.

As shown in <FIG>, subsequently in step S4, the donor plate is cooled down so that the patterned layer <NUM> is retracted away from the target. Also the retraction can take place rapidly, for example in <NUM> to <NUM> microseconds, e.g. in a time frame of <NUM> microseconds the plate is cooled down to a uniform temperature of a few tens of degrees e.g. 40oC and fully retracted to the plate carrier <NUM>.

In the embodiment just described the ejection of the deposition substance <NUM> is initiated by the step of resistively heating.

As illustrated in <FIG>, the rapid retraction of the donor plate <NUM> contributes to a better release of the deposition substance <NUM>. In the examples shown the donor plate <NUM> has retracted away from the target <NUM> over a distance PG. The distance PG maybe a fraction of the print thickness PT, i.e. the dept of the recesses in the patterned surface of the plate, e.g. PG is about <NUM>/<NUM> to ½ of the print thickness PT. In the example shown in <FIG>, retraction is relatively slow, e.g. has taken a few milliseconds, e.g. <NUM> milliseconds. In this timeframe the deposition substance 2a, could flow out, therewith contact the edges of the recess from which it was ejected, and stick thereto after solidification.

<FIG> shows the situation wherein retraction has taken place in a few microseconds to a few tens of microseconds, e.g. in <NUM> microseconds. In this timeframe the deposition substance 2b does not have sufficient time to flow out, so that is avoided that it sticks to the donor plate after ejection.

In an alternative embodiment a donor plate as shown in <FIG> is used that has respective, independently controllable sets of one or more resistive heating elements arranged between the second electrically insulating layer <NUM> and the patterned layer <NUM> in respective zones defined by respective ones of the recesses. In operation the donor plate may be heated in step S2 at its first main surface <NUM> to a temperature that is sufficiently high to deform the plate, and in step S3, the ejection of deposition substance <NUM> can be accurately controlled by selectively providing electric energy to a specific selected control electrode 212a, 212b,. 212n of a set of one or more dedicated resistive heating elements. The resistive heating elements may share a common second electrode <NUM>. Therewith the timing of the ejection can be controlled independently from the timing of the deformation of the plate.

In the embodiment, ejection of the deposition substance <NUM> can be controlled to take place in a particular state of the donor plate <NUM>.

As an example, the velocity with which the deposition substance <NUM> is ejected in step S3 can be increased by timing the ejection when the donor plate <NUM> is moving towards the target <NUM>. Suppose for example, that the velocity of the donor plate <NUM> in the direction of the target <NUM> induced in step S2 as a result of its thermal expansion is <NUM>/s and that the deposition substance <NUM> is ejected from the donor plate <NUM> with a velocity of <NUM>/s by energizing one or more of the dedicated resistive heating elements, then the deposition substance <NUM> will be transferred with a velocity of <NUM>/s towards the target <NUM>.

The opposite would be possible too. If the deposition substance <NUM> is ejected at <NUM>/s while the donor plate <NUM> is retracting at <NUM>/s then the resulting velocity is <NUM>/s, which makes gravity causing the deposition substance to fall onto the target <NUM>. This reduced impact speed could be beneficial for preventing lower viscous deposition substances to splash, or making it possible to wrap ink around surfaces without breaking up due to high shear forces.

<FIG> shows an example of the deposition device wherein the donor plate <NUM> in a radially outward direction has a central section 1C, a resistively heatable intermediary section 1I and a peripheral section 1P. The central section 1C comprises a section of the flexible substrate <NUM>, with the electrode layer <NUM>, the first electrically insulating layer <NUM>, the resistive heater layer <NUM>, the second electrically insulating layer <NUM> and the patterned layer <NUM>. The intermediate section 1I surrounds the central section 1C and the donor plate <NUM> is attached with its peripheral section 1P to the plate carrier <NUM>. In the example shown, the central section 1C has mutually a bottom resistive heater layer 13CB and a top resistive heater layer 13CT which are arranged at mutually opposite sides of a neutral plane defined by the flexible substrate <NUM>. The intermediary section 1I is also resistively heatable in that it has a bottom resistive heater layer 13IB and a top resistive heater layer 13IT.

By resistively heating the intermediary section 1I, the central section 1C of the donor plate can be translated towards the target without substantial deformation. Deformation of the central section 1C is further mitigated in that the bottom resistive heater layer 13CB and the top resistive heater layer 13CT are controlled to avoid a substantial temperature gradient in the central section 1C in a direction of its surface normal. Also the intermediary section 1I may have a thermal expansion coefficient greater than that of the central section 1C, for example by a local modification of the substrate. Therewith a substantial deformation of the intermediary section 1I can be achieved. In one of the examples electrodes for supplying the resistive heaters 13CB, 13CT, 13IB, 13IT may be provided from copper an be embedded in a silicon substrate. Copper has a thermal expansion coefficient of about <NUM> ppm/K, while silicon is around <NUM> ppm/K. Moreover, copper has a very high thermal conductivity. This has the advantage that heating/cooling and therewith expansion and retraction of the plate can be achieved even more rapidly.

<FIG> shows two further embodiments of a deposition device. In the case of the deposition device of <FIG>, the deposition plate <NUM> has a central section 1C with a thickness that increases in a radially outward direction. This is achieved in that the flexible substrate <NUM> of the plate has the radially increasing thickness.

Also in the embodiment of <FIG>, the central section 1C has a thickness that increases in a radially outward direction. However, in this embodiment this is achieved in that a coating <NUM> having a low thermal conductivity and having the appropriate thickness profile is applied on the second main surface <NUM> of the flexible substrate <NUM>. The flexible substrate <NUM> proper is of uniform thickness in this case.

The thermal equilibration time is relatively low in the center of the plate as compared to that in a more radially outward direction. As a result, a higher thermal expansion occurs in the periphery of the plate while the plate remains substantially flat in the printing area.

It is noted that one or more thermal buffer layers, e.g. from a ceramic material, such as SiO2 may be provided between the flexible substrate <NUM> and the resistive heater layer <NUM> to provide for a reduced heatflux into the substrate. Simulations were performed which are described below with reference to <FIG>, <FIG>.

<FIG> schematically shows the simulated donor plate <NUM> for deposition of the substance <NUM>, in this case an ink. The donor plate is provided with a silicon substrate <NUM> having a thickness of <NUM> micron. The substrate <NUM> is provided with a copper electrode layer <NUM> at its first main surface <NUM> (indicated by a dashed line). The electrode layer comprises a first electrode <NUM> and a second electrode <NUM> of a complementary shape having a thickness of <NUM> micron that are embedded in the silicon substrate at its first main surface <NUM> and that are electrically insulated from each other by the material of the substrate. It is noted that not all elements in the drawing are presented at the same scale. For example, for clarity only the upper portion of the substrate <NUM> is shown. More details about the dimensions and the material properties used for the simulation are provided in the table below. Subsequent to the electrode layer <NUM>, the simulated donor plate <NUM> comprises a first electrically insulating layer <NUM> of SiO2, a molybdenum resistive heater layer <NUM> a second electrically insulating layer <NUM> of Si3N4) and a patterned layer provided with one or more recesses <NUM> for holding the deposition substance <NUM> to be deposited. It is noted that <FIG> only shows a portion where the simulated donor plate forms a recess <NUM> in the patterned layer. As shown in <FIG>, the resistive heater layer <NUM> is electrically connected to each of a contact surface of the first electrode <NUM> and a contact surface of the second electrode <NUM> via a respective slit <NUM>, <NUM> in the first electrically insulating layer.

<FIG> further shows a heat spreader layer <NUM> at a bottom of the recess <NUM>. The heat spreader layer <NUM> is formed of tungsten and has a thickness of <NUM> micron.

More details are presented in the following table.

The simulation was performed with a fixed setting for the heat flux generated in the Mo layer of <NUM> kW/cm<NUM>. The thickness of the second insulating layer <NUM> and the dimensions of the slits <NUM>, <NUM> were variable.

<FIG> show three exemplary simulation settings denoted as Stack <NUM>, Stack <NUM> and Stack <NUM> respectively.

In <FIG> the slit tapers outward in a direction away from the first electrode <NUM> from a smallest width of <NUM> micron to a largest width of <NUM> micron, and the second insulating layer <NUM> has a thickness of <NUM>.

In <FIG> the slit tapers outward in a direction away from the first electrode <NUM> from a smallest width of <NUM> micron to a largest width of <NUM> micron, and the second insulating layer <NUM> has a thickness of <NUM>. In each case the molybdenum layer <NUM> electrically contacts the first electrode <NUM> in the narrow part of the slit <NUM>. The same applies to the electrical contact between the molybdenum layer <NUM> with the second electrode <NUM> in the slit <NUM>. Because the electrical connections with the first and the second electrode are the same, only the electrical connection with the first electrode is shown.

<FIG> shows a temperature distribution in the substance for each of these cases as a function of the position from left to right in the drawing. As a reference, the positions of the slits <NUM>, <NUM> are indicated. <FIG> shows the absolute value of the temperature, whereas <FIG> shows the deviation of the temperature from the average temperature. To take into account the different thickness of the second insulating layer <NUM> in Stack <NUM> on the one hand and Stacks <NUM>,<NUM> on the other hand, the temperature distribution of Stack <NUM> is determined after <NUM> microseconds and the temperature distribution of Stacks <NUM> and <NUM> is determined after <NUM> microseconds. As can best be seen in <FIG>, the temperature distribution of Stacks <NUM> and <NUM> closely resemble each other. The temperature distribution of Stack <NUM> is more uniform as compared to Stacks <NUM> and <NUM>. This is explained in that the contact area of the resistive layer <NUM> with the electrode <NUM>, wherein the resistive layer does not generate heat, is substantially smaller in Stack <NUM> than in each of Stacks <NUM> and <NUM>.

As can further be observed in <FIG> it is achieved that the temperature above the slits <NUM>, <NUM> achieves a maximum value that is almost equal to the average temperature. This can be explained by the following. Firstly, due to the fact that the slits have slanting sidewalls, a relatively large surface is provided relative to the projection of this surface in the recess <NUM>. Therewith the heat flux, the power per unit area, in the projection of the sidewall surface, is higher than the heat flux generated in the side walls. Secondly, depending on the deposition technique used for the resistive layer, it can be achieved that the heat flux generated in the side walls of the resistive layer is larger than the heat flux generated in the areas of the resistive layer between the slits. For example, if the resistive layer <NUM> is deposited by sputtering, the material for deposition is distributed on the sidewalls over a larger area than in the areas of the resistive layer between the slits. Therewith the thickness of the resistive layer at the sidewalls is less than the thickness of the resistive layer between the slits. Due the relatively high resistance of the resistive layer present on the sidewalls therein a relatively high heat flux is generated. By a proper choice of the thickness of the first insulating layer <NUM>, and the dimensions of the tapering slits <NUM>, <NUM>, i.e. the width thereof at the contact-area with the electrode <NUM> and the width thereof at the main surface of the resistive layer, it can be achieved that the average heat flux in the projected area of the slit <NUM>, <NUM> is approximately equal to the heat flux in the areas between the slits. It is noted that the heat flux in the recess can be further homogenized by a heat distribution layer <NUM>, as shown in <FIG> and <FIG>. The skilled person can therewith make a tradeoff between a desired extent of homogeneity and an efficiency of the device. If a high extent of homogeneity is desired, a relatively thick heat distribution layer <NUM> may be selected at the cost of some loss of efficiency, in that a longer heating time and more energy is required to obtain a desired average temperature. Accordingly, if the efficiency is more important, a thinner heat distribution layer <NUM> may be chosen.

Claim 1:
A donor plate (<NUM>) for deposition of a deposition substance (<NUM>) on a target (<NUM>), the donor plate comprising a flexible substrate (<NUM>), which at a first main surface (<NUM>) has a patterned layer (<NUM>) provided with one or more recesses (<NUM>) for holding deposition substance (<NUM>) to be deposited on the target,
characterized in that the flexible substrate (<NUM>) at the first main surface (<NUM>) subsequently has an electrode layer (<NUM>), a first electrically insulating layer (<NUM>), a resistive heater layer (<NUM>), a second electrically insulating layer (<NUM>) and the patterned layer, wherein the electrode layer (<NUM>) comprises a first and a second electrode (<NUM>, <NUM>) of a complementary shape and being electrically insulated from each other, and wherein the resistive heater layer (<NUM>) is electrically connected to each of a contact surface of the first electrode (<NUM>) and a contact surface of the second electrode (<NUM>) via at least one respective slit (<NUM>, <NUM>) in the first electrically insulating layer.