Patent Description:
Thermal evaporation of metals is a commonly used laboratory technique for the deposition of contact electrodes in test arrays of electronic devices. Generally, the source materials are resistively heated to the point where they sublime and condense on to the substrate forming a thin film. There is minimal heat transfer or physical damage to the substrate and the resultant films are usually of high purity due to the lack of any gas inclusion (as in sputtering) and the high vacuum needed for this process. Where metal films of very high purity are required, for example in the fabrication of electrochemical, or bio sensors and where surface purity may impact performance, evaporation is preferred. These attributes encourage evaporation to be used as a research and development technique to deposit electrodes on polymeric organic substrates without damaging their physical and chemical structure. However, evaporation is difficult to scale up as uniformity over large areas is poor, throughput is low, and it is therefore not widely used in industrial manufacturing processes.

In the industrial fabrication of electronic devices including transistor arrays, manufacturers use plasma processes to deposit the metal electrodes. This is due to the high throughput of the sputter process coupled with the fact that sputter tools already exist on most electronics manufacturing lines. The effect of plasma-induced damage to low permittivity organic dielectrics is known and was reported by<NPL>. It is particularly problematic when amorphous polymeric organic materials are being used as the layer directly exposed to plasma. This is due to bombardment from ions, electrons and UV photons generated during plasma sputtering which cause structural damage to the organic material. Furthermore, plasma-induced damage to amorphous perfluoropolymer layers was reported in the <NPL>[<NUM>] where it stated that C-F bonds are particularly prone to plasma damage. The deep UV photons generated have energies in the range of <NUM> - <NUM> eV which is sufficient to break C-C, C-O and C-F bonds in the Cytop™. These damaged bonds may cross-link or recombine forming defects/dipoles and traps at, or close to the OSC /OGI interface.

In organic transistors, low k dielectric materials such as amorphous perfluoropolymers are preferred organic gate insulator materials, particularly when using small molecule organic semiconductors (OSCs) in combination with polymeric binders. <NPL>, reported that the use of low permittivity OGI materials in OTFTs minimises interfacial trapping between the organic semiconductor and the organic gate insulator (OGI). This is due to minimising modulation of random dipole moments, resulting in organic thin film transistors having close to ideal electrical characteristics.

Particularly preferred OGI materials for top gate (TG) OTFTs include perfluoropolymers such as Cytop™, Hyflon™ and TEFLON AF. ™ In this case, the perfluoropolymer is the layer within the organic thin film transistor that is directly exposed to plasma sputtering (layer <NUM>, <FIG>). When top gate OTFTs comprising materials such as Cytop™ as gate insulator are exposed to plasma sputtering processes, UV photons cause irreversible damage to the chemistry of the Cytop™ layer. In the OTFT, this damage is manifest as a number of undesirable electrical characteristics including high threshold voltage values (Vth), high turn on voltages (Vto), high subthreshold swing (SS), high off currents, low Ion/off ratios and poor bias stress stability. The importance of these electrical parameters is well understood by the skilled person.

The deleterious impact of the high energy particles from plasma sputtering on the performance of organic field-effect transistors incorporating a perfluoropolymer OGI is shown in <FIG> shows that when top gate TFTs were fabricated without an OSPL on top of the OGI (TFTS-SKBL756) compared to the control TFT (SKBL808) made with an evaporated gate, the Vth value increased from <NUM> volts to <NUM> volts, Vto increased from <NUM> volts to <NUM> volts and the subthreshold swing increased from <NUM> volts/decade to <NUM> volts/decade. <FIG> demonstrates that TFTs fabricated with an OSPL layer in-situ prior to exposure to the sputter process and deposition of the gate metal retain their pre-plasma electrical properties. The resulting higher operating voltages in turn results in devices having higher power consumption. Cytop ™ is known to suffer damage in an argon plasma. With the said OSPL in-situ, there is minimal change in the post-plasma values for Vth, Vto, SS, Ion, Ioff and lon/off ratio (≤<NUM>% change).

<CIT> describes a process for preparing organic field effect transistors (OFETs) incorporating a layer to minimise damage to exposed parts of the surface of the dielectric layer. The protective layer is deposited onto the OGI prior to exposure to plasma or sputtering processes and is optionally removed from the device. The patent discloses that preferred protective layers are perfluoropolymers such as Cytop™ (refer to page <NUM>, lines <NUM>-<NUM> and page <NUM> lines <NUM>-<NUM>). However, in direct contradiction to the teaching of <CIT>, we have found that Cytop™ is irreversibly damaged on exposure to even low levels of low energy Ar plasma. Beside the UV generated particles, other energetic particles may be formed during a typical sputter process, such as reflected Ar (<NUM> - <NUM> eV and sputtered atoms (~<NUM> eV). The energy of these particles is sufficient to break C-C (~<NUM> eV), C-O (~<NUM> eV) and C-F bonds (~<NUM> eV) within the organic layers.

Cytop™ and perfluoropolymers as a class of materials afford no protection from sputter damage and therefore should not be used as the protective layer in OTFTs.

One of the problems that is solved by the invention is how to uniformly solution coat an OSPL ink onto a low surface energy OGI material such as CYTOP™ that has a surface free energy of only <NUM>-<NUM> mN/m without the need to use a surface pre-treatment process such as plasma or chemical etching of the OGI to increase its surface energy. In the case of OTFTs, plasma or chemical treatment would irreversibly damage the OGI and render the OTFT useless. <CIT> does not provide any teaching on how to achieve uniform solution coating onto perfluoropolymers, whereas our invention solves this industrially relevant technical problem. Furthermore, in TG OTFTs as in the invention, if the same material was solution coated as the OSPL onto an amorphous perfluoropolymer OGI it would simply re-dissolve the OGI. The teaching in <CIT> is not applicable to TG devices. A further major difference in this invention compared to <CIT> is the requirement for an OSPL having a higher permittivity than the OGI for the benefits of higher capacitance in the TFT channel as previously described. <CIT> prefers low permittivity OGI and low permittivity OSPL.

Document <CIT> relates to processes of manufacturing organic field effect devices comprising depositing from a solution an organic semiconductior layer, and depositing from a solution a layer of low permittivity insulating material forming at least a part of the gate insulator, such that the low permittivity insulating layer is incontact with the OSC layer. It also discloses organic field effect devices manufactured by the process.

Disclosed herein is an organic gate insulator (OGI) layer having a dielectric constant (k) < <NUM> @ <NUM>, said organic gate insulator layer being over-coated with a cross-linked organic layer (OSPL).

Preferably, the cross-linked organic layer has a permittivity (k) > <NUM> @ <NUM>, more preferably the cross-linked organic layer has a k > <NUM> at <NUM>.

Also disclosed herein is an organic thin film transistor, comprising a substrate, one or more source/drain electrodes, at least one gate electrode, an organic semiconductor layer, and an organic gate insulator layer comprising a dielectric material having a dielectric constant (k) < <NUM> @ <NUM>, said organic gate insulator layer being over-coated with a cross-linked organic layer. Preferably the cross-linked organic layer has a permittivity (k) > <NUM> @ <NUM>, more preferably the cross-linked organic layer has a k > <NUM> at <NUM>.

Also disclosed herein is an electronic device comprising an organic thin film transistor as described above.

In a first aspect of the present invention, there is provided a solution according to claim <NUM>. The solution comprises (a) at least one multi-functional acrylate, (b) a non-acrylate organic solvent, (c) a fluoro surfactant and an acrylate- and/or methacrylate-functionalised silicone surfactant, and (d) at least one type of photo-initiator. The multi-functional acrylate comprises (a1) a multi-functional acrylate compound containing a nitrogen-containing cyclic core having at least two pendant acrylate moieties, and (a2) a polyacrylate monomer having an oxy or polyoxy-alkane core. Such a solution is commonly referred to as an ink in this technical field.

In a second aspect of the invention there is provided a process for solution deposition of a cross-linkable organic layer on to an organic gate insulator according to claim <NUM>. The OGI has a surface free energy of <NUM> mN/m or less. The solution comprises at least one fluorosurfactant, at least one, acrylate- and/or methacrylate-functionalised silicone surfactant, at least one multi-functional acrylate, and one or more initiators. In this process, the cross-linked organic layer (OSPL) is formed from the solution according to the fourth aspect of the invention. This process preferably affords a continuous, defect-free, organic layer followed by crosslinking of the organic cross-linkable layer. This aspect of the invention enables the effective over-coating of low surface energy OGIs, in particular, fluoropolymers. The approach developed avoids the need to use aggressive chemical or plasma etching of the fluoropolymer surface prior to ink deposition; neither of which are desirable when fabricating organic thin film transistors.

Fluorosurfactants used in the present invention are synthetic organofluorine compounds that have multiple fluorine atoms. They can be polyfluorinated or fluorocarbon-based (perfluorinated). As surfactants, they are more effective at lowering the surface tension of water than comparable hydrocarbon surfactants. Preferably, they have a fluorinated "tail" and a hydrophilic "head.

The cross-linkable organic layer has excellent curing characteristics in air or nitrogen and is preferably capable of forming on the surface of a substrate a substantially planar cured layer having excellent hardness, high plasma resistance, excellent thermal durability and high tensile strength.

In all aspects of the present invention, the cross-linked organic layer is referred to as the Organic Sputter Protection Layer (OSPL). This is preferably coated directly on to a low k (dielectric constant) organic gate insulator (OGI) layer to minimise damage to the OGI from a sputter/plasma process.

Specifically, the OSPL preferably has a high crosslink density of ≥ <NUM> pencil hardness and preferably reaches > <NUM>% conversion by FTIR on exposure to <NUM>. 4J/cm<NUM> at <NUM> wavelength (This provides high resistance to plasma-induced damage, high resistance to chemical damage, high thermal durability and high tensile strength).

The OSPL also reduces delamination of the low k OGI layer from the underlying interface that can occur.

It is also possible to overcoat one OSPL with a second OSPL. Essentially, the first OSPL can be used as a primer for the second OSLP, which may have the same or different properties to the first OSPL. In this way, the OGI may have multiple OSPL layers built up on its surface.

The cross-linkable OSPL may be cured chemically, thermally or photochemically. The cross-linked OSPL preferably has a pencil hardness, of between <NUM> to <NUM>,preferably between <NUM> to <NUM> measured using ASTM-D3363.

The present invention also enables the over-coating of any low surface energy polymer layer. According to all aspects of the present invention, the OGI layer has a surface free energy (SFE) ≤ <NUM> mN/m, preferably less than 20mN/m and more preferably less than <NUM> mN/m. The approach avoids the need to use an aggressive chemical or plasma etching pre-treatment of the low surface energy organic gate insulator prior to OSPL deposition, neither of which are desirable when fabricating thin film transistors due to resulting ion-doping of the OTFTs.

According to a preferred embodiment of the first aspect of the present invention the OSPL ink has a surface tension in the range of <NUM> to <NUM> mN/m, more preferably <NUM> to <NUM> mN/m. The relatively low surface tension of the OSPL ink enables wetting of the OGI. This is achieved by using a combination of a fluorosurfactant and a silicone surfactant. Preferably, the fluorosurfactant is a perfluorosurfactant. The silicone surfactant is a silicone surfactant having acrylate or methacrylate functionalities. Examples of such silicone surfactants are described in <CIT>. Alternatively, such silicone surfactants are preferably polydimethyl or polytrimethyl siloxane polymers, modified with one or more acrylate and/or methacrylate functionalities. Such siloxane polymers preferably also contain a hydrophilic moiety, such as a phosphate or sulphate moiety. For example, preferred polymers include Dowsil™ fa <NUM> silicone acrylate, which is an acrylates/polytrimethylsiloxymethacrylate copolymer (and) laureth-<NUM> phosphate copolymer. Further preferred silicone surfactants include Silmer ACR D208, Silmer ACR Di-<NUM>, Silmer ACR Di-<NUM>, Silmer ACR Di-<NUM>, Silmer ACR Di-<NUM>-<NUM> and Silmer ACR Di-<NUM>, obtainable from Siltech.

It is postulated that this combination is effective because the fluorosurfactant migrates to the OGI interface, and the silicone surfactant is crosslinked into the bulk of the OSPL layer.

Fluorosurfactants used in the present invention include perfluoro oligomers and perfluoropolymers. Examples of fluorosurfactants suitable for use include linear chain fluorinated functional groups of F(CF2)n- where n = <NUM> to <NUM> Such surfactants are sold under the trade name CAPSTONE, MEGAFACE or FC-<NUM>, sold by <NUM> under the Novec trade name. In particular, MEGAFACE F-<NUM> from DIC is preferred.

The invention aims to protect the OGI from plasma-induced damage by providing a highly cross-linked OSPL coated directly onto the OGI. This in turn, enables OTFT arrays that retain their pre-sputter/plasma electronic characteristics, such as low threshold voltage values (preferably ΔVth post plasma < 2V @ Vg volts (measured in the linear regime), low turn on voltages (preferably Vto post plasma <3V) low off currents (preferably < <NUM>-<NUM>A), low change in sub-threshold swing values (preferably ΔSS post plasma <<NUM>. 5V) and high Ion/off ratios (preferably ≥<NUM><NUM>). Benefits include OTFTs having lower threshold voltage values, lower turn on voltages, improved sub-threshold swing, higher on currents, low off currents and high on/off ratios, all of which enable improved driving capability. Lower off currents reduces leakage currents (and concomitantly power consumption in the off state). Low Vth is required to reduce the gate voltage needed to maintain an OTFT in the off state. Low Vth combined with a low sub-threshold swing reduces power consumption and improves the switching speed of the device.

The OSPL preferably has a higher permittivity than the OGI. For example, the OGI material has a dielectric constant (k) < <NUM> @ <NUM>, preferably < <NUM> @ <NUM>. The OSPL preferably has a higher permittivity than the OGI layer, typically > <NUM> unit higher than the OGI. The OSPL has a dielectric constant (k) > <NUM> @ <NUM>, preferably > <NUM> @ <NUM>, preferably > <NUM> @ <NUM>. Such higher permittivity is provided by the polar, multi-functional acrylate components of the OSPL ink (discussed in detail below). This feature can advantageously be used to increase the overall capacitance of the OGI/OSPL layer in the active channel region of the transistor. A higher gate capacitance is desirable to reduce device operating voltages. However, this is best achieved by increasing the permittivity rather than reducing the thickness of the OGI, to prevent dielectric breakdown. The dual layer formed by the low permittivity OGI and higher permittivity OSPL has an effective permittivity higher than the OGI, increasing capacitance and maintaining dielectric integrity, whilst retaining the benefit of having a low permittivity insulator directly in contact with the OSC as explained above. The sputter protective layer remains in place in the OSC/OGI channel region of the OTFT throughout the lifetime of the device and is not removed.

The OSPL preferably has a permittivity lower than the OSC layer.

In a particularly preferred embodiment, the OTFTs incorporating the solution of the present invention, or incorporating the OSPL formed by the process of the present invention, can contain more than one OSPL in the OTFT stack.

Preferably, the organic gate insulator (OGI) layer comprises a low permittivity polymer having a dielectric constant (k) < <NUM> @ <NUM>, for example a perfluoropolymer. As used herein, low k means a dielectric constant of less than <NUM> when measured at <NUM>, preferably less than <NUM>, preferably less than <NUM>. Preferably, the low dielectric constant (k) polymer has a dielectric constant in the range of <NUM> to <NUM>. In the invention, high permittivity means > <NUM>, more preferably > <NUM>, more preferably > <NUM> @<NUM>.

Preferably, the OSPL has a permittivity (k) > <NUM> @ <NUM>, preferably k > <NUM> and more preferably ><NUM> at <NUM>. Where more than one OSPL is present, they may have different permittivity to one another. This may be affected by virtue of their relative chemical composition.

Some examples of low permittivity polymers preferably include perfluoropolymers, benzocyclobutene polymers (BCB), parylene, polyvinylidene fluoride (PVDF) polymers, cyclic olefin copolymers (e.g. norbornene, TOPAS™) polymers, adamantyl polymers, perfluorocyclobutylidene polymers (PFCB), polymethylsiloxane (PDMS), and mixtures thereof.

The crosslinkable OSPL is coated on top of the OGI using any solution coating technique, preferably including spin coating, spray coating, slot-die coating, inkjet printing. The OSPL is crosslinked to provide a continuous layer.

Preferably, the perfluoropolymer OGI is selected from the chemical class consisting of Cytop™, Hyflon™ and TEFLON AF™. These perfluoropolymers have the structures shown below. <CHM>
<CHM>
wherein * indicates the point of attachment of the repeat unit to the rest of the polymer and n is an integer (n being that conventionally used for such perfluoropolymers).

In one embodiment, Cytop is represented as a homopolymer of monomer on left had side of the structure above. Accordingly, preferably m=<NUM> and n=<NUM> for the Cytop example given above.

Preferred amorphous perfluorinated polymers are available from Du Pont (Teflon® AF), Asahi Glass (as Cytop®), and Solvay (as Hyflon® AD).

Teflon® AF and Hyflon® AD are copolymers of <NUM>,<NUM>-bis(trifluoromethyl)-<NUM>,<NUM>-difluoro-<NUM>,<NUM>-dioxole (I) and <NUM>,<NUM>-bis(trifluoromethyl)-<NUM>-fluoro-<NUM>-trifluoromethoxy-<NUM>,<NUM>-dioxole (II) with tetrafluoroethylene, respectively.

Cytop® <NUM> is a most preferred OGI material for use in the present invention.

These materials are all commercially available and their production is well known in the art.

The organic gate insulator (OGI) layer can be completely protected from sputter damage by the present invention and the resulting OTFTs retain their pre-sputter electrical characteristics.

The cross-linked protective organic layer of the present invention is preferably a free-radical photocured, crosslinked layer.

Preferably, the OSPL layer is in the range of <NUM>-<NUM> thick, more preferably <NUM>-<NUM> thick, most preferably <NUM>-<NUM> thick. The thickness of the OSPL layer required depends upon the energy and duration of the plasma process used to deposit the gate metal. The higher the plasma energy, or the longer the exposure time, the thicker the required OSPL layer to provide protection from sputter damage. For example, sputter deposition of a gold gate metal (approx. <NUM> thick) requires an OSPL of only <NUM>-<NUM> thickness. Sputter yields of noble metals such as Au or Ag are <NUM> - <NUM> times higher than for Al or Mo. Therefore, to afford the same level of protection, thicker layers of OSPL (~ <NUM>-<NUM>) are required when depositing metals such as Al or Mo.

The OSPL is preferably obtainable by polymerising an ink composition comprising at least one multi-functional acrylate. The multi-functional acrylate should preferably be capable of cross-linking with other components of the ink.

The OSPL is preferably obtainable by solution coating said ink composition onto the OGI.

The OSPL preferably has a cross-link density in the range of <NUM> to <NUM> pencil hardness.

The multi-functional acrylate of the solution according to the first aspect contains a nitrogen-containing core having at least two pendant acrylate moieties (a1) a multi-functional acrylate compound containing a nitrogen-containing cyclic core having at least two pendant acrylate moieties, and (a2) a polyacrylate monomer having an oxy or polyoxy-alkane core.

The OSPL formed from the solution is preferably obtainable by polymerising an ink composition comprising (a1) a first multi-functional acrylate compound containing a nitrogen-containing core having at least two pendant acrylate moieties, and (a2) a second multi-functional acrylate compound having an oxy- or polyoxy-alkane core.

Both components (a1) and (a2) are preferably not silicone based, and are preferably not surfactants.

Preferably the multi-functional acrylate compound (a1) contains at least two pendant (acryloyloxy) ethyl moieties, preferably three pendant (acryloyloxy) ethyl moieties. The multi-functional acrylate compound may have up to six acrylate moieties.

The multi-functional acrylate compound (a1) of the OSPL comprises a nitrogen-containing core having at least two pendant acrylate moieties and is preferably an isocyanurate core with at least two acrylate groups, preferably at least two (acryloyloxy)ethyl moieties, preferably three (acryloyloxy)ethyl moieties.

Specific preferred examples of the the multi-functional acrylate compound (a1) of the OSPL are isocyanurate compounds selected from the group consisting of Tris (<NUM>-hydroxy ethyl) isocyanurate triacrylate, Photomer <NUM> Amine modified polyether acrylate, Photomer <NUM> Amine modified polyether acrylate, Sartomer CN550 and Sartomer CN503.

Preferably the multi-functional acrylate compound (a1) of the OSPL is tris[<NUM>-(acryloyloxy)ethyl] isocyanurate, having the following structure:
<CHM>.

The multi-functional acrylate compound (a1) of the OSPL provides the required cross-link density of the cured layer. This component preferably has a high Tg which imparts hardness to the layer.

The multi-functional acrylate monomer compound (a2) is used to provide fast cure, and to impart coating hardness and chemical resistance to the OSPL layer.

Preferably, the high reactivity monomer (a2) is a multifunctional acrylate compound having an oxy or polyoxy-alkane core and at least two acrylate groups. More preferably an oxy- or polyoxy-C<NUM>-<NUM> alkane core, such as a polyoxy-C<NUM>-<NUM> alkane core. Some examples of (a2) acrylates include trimethylolpropane triacrylate, ditrimethylolpropane tetra-acrylate (DiTMPTA), dipentaerythritol hexaacrylate, pentaerythritol tetraacrylate, polyester hexaacrylate , dipentaerythritol hexaacrylate (DPHA) and multifunctional acrylate oligomers such as Photomer <NUM> Polyester tetraacrylate, Photomer <NUM> Polyester hexaacrylate, Photomer <NUM> Multi-functional acrylate, Photomer <NUM> Aliphatic urethane hexaacrylate, Photomer <NUM> Aliphatic urethane hexaacrylate, and Cresol novolac epoxy acrylate.

Preferably, the monomer (a2) comprises a polyoxy-C<NUM>-<NUM> alkane core moiety having at least two pendant acrylate moieties, preferably three pendant acrylate moieties. Preferably, the monomer (a2) comprises a polyoxy-C<NUM>-<NUM> alkane core having three pendant acrylate moieties. The monomer (a2) may have up to six acrylate moieties.

Preferably, the multifunctional acrylate monomer (a2) comprises (is) trimethylolpropane triacrylate.

Preferably, the multifunctional acrylate monomer (a2) is highly reactive, thereby enabling a fast cure of the OSPL in both surface and bulk cure.

The combination of monomers (a1) and (a2) enable a high degree of cross linking.

In addition, it is preferable that the OSPL ink further includes a relatively high viscosity component, so that once it has been coated onto the OGI, the higher viscosity prevents the wet film from reticulating from the OGI surface.

It is preferable that after solvent evaporation from the OSPL ink the viscosity of the pre-cured OSPL layer should be > 2000cPs to prevent reticulation from the OGI surface. Therefore, preferably, the ink composition comprises a multifunctional acrylate oligomer having a viscosity of > 3000MPa. The multifunctional acrylate oligomer optionally comprises a bisphenol acrylate oligomer.

The OSPL is preferably obtainable by polymerising a composition according to the first aspect of the present invention. The non-acrylate solvent (b) may be used to adjust the viscosity of the composition during preparation or in a coating operation, or to improve wetting with respect to a substrate to be coated.

Examples of the solvent (b) include aromatic hydrocarbons such as benzene, toluene, xylene, cumene, ethylbenzene, aliphatic hydrocarbons such as hexane, heptane, octane, petroleum ether, ligroin, cyclohexane and methylcyclohexane; halogenated hydrocarbons chlorobenzene and bromobenzene; alcohols such as methanol, ethanol, isopropanol, butanol, pentanol, hexanol, cyclopentanol, cyclohexanol, ethylene glycol, propylene glycol, propylene carbonate, glycerol, ethylene glycol monomethyl ether and diethylene glycol; ketones such as acetone, methyl ethyl ketone, methyl isobutyl ketone and cyclohexanone; ethers such as diethyl ether, dipropyl ether, butyl ethyl ether, dibutyl ether, ethylene glycol, propylene carbonate, dimethyl ether and diethylene glycol dimethyl ether; nitriles such as acetonitrile, propionitrile and capronitrile; and esters such as methyl formate, ethyl formate, methyl acetate, ethyl acetate, propyl acetate, isobutyl acetate, butyl acetate, pentyl acetate, methyl benzoate, ethyl benzoate, and lactones, such as gamma butyrolactone. Preferably the organic solvent comprises or consists of ethyl lactate.

The OSPL is preferably obtainable by polymerising a composition according to the first aspect of the invention.

The photo-cure mechanism should not result in ionic contaminants being present in the OTFT device. This means that photoresist materials that include photogenerated acids are not preferred.

The specific acrylate components of the OSPL are selected to be orthogonal to the underlying OGI layer, impart fast cure speed, provide excellent depth of cure and surface cure and most importantly to afford high cross-link density. Crosslink density is thought to correlate with resistance to sputter damage.

The organic semiconductor layer used in the present invention preferably comprises at least one semiconducting ink. Preferably, the ink comprises a small molecule polyacene and/or polytriarylamine binder formulation. Preferred semiconducting inks include those described in <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>,<CIT>, <CIT>, <CIT>, <CIT> <CIT>, <CIT>, <CIT>, <CIT>, <CIT>.

Other OSC materials that can be used include discrete compounds, oligomers and derivatives of compounds of the following: conjugated hydrocarbon polymers such as of polyacene, polyphenylene, poly(phenylene vinylene), polyfluorene including oligomers of those conjugated hydrocarbon polymers; condensed aromatic hydrocarbons such as tetracene, chrysene, pentacene, pyrene, perylene, coronene, diketopyrrolopyrroles, substituted benzothienobenzothiophenes (C8-BTBT), dinaphthothienothiophenes (DNTT) or substituted derivatives of these; oligomeric para substituted phenylenes such as p-quaterphenyl (p-4P), p-quinquephenyl (p-5P), p-sexiphenyl (p-6P), or soluble substituted derivatives of these; conjugated heterocyclic polymers such as poly(<NUM>-substituted thiophene), poly(<NUM>,<NUM>-bisubstituted thiophene), polybenzothiophene, polyisothianapthene, poly([Lambda]/-substituted pyrrole), poly(<NUM>-substituted pyrrole), poly(<NUM>,<NUM>-bisubstituted pyrrole), polyfuran, polypyridine, poly-<NUM> ,<NUM>,<NUM>-oxadiazoles, polyisothianaphthene, poly([Lambda]/-substituted aniline), poly(<NUM>-substituted aniline), poly(<NUM>-substituted aniline), poly(<NUM>,<NUM>-bisubstituted aniline), polyazulene, polypyrene; pyrazoline compounds; polyselenophene; polybenzofuran; polyindole; polypyridazine; benzidine compounds; stilbene compounds; triazines; substituted metallo- or metal-free porphines, phthalocyanines, fluorophthalocyanines, naphthalocyanines, naphthalene diimides or fluoronaphthalocyanines; C60 and C70 fullerenes; A/. [Lambda]/'-dialkyl, substituted dialkyl, diaryl or substituted diaryl-<NUM> ,<NUM>,<NUM>,<NUM>-naphthalenetetracarboxylic diimide and fluoro derivatives; [Lambda]/,[Lambda]/'-dialkyl, substituted dialkyl, diaryl or substituted diaryl <NUM>,<NUM>,<NUM>,<NUM>-perylenetetracarboxylicdiimide; bathophenanthroline; diphenoquinones; <NUM> ,<NUM>,<NUM>-oxadiazoles; <NUM> ,<NUM> ,<NUM>,<NUM>-tetracyanonaptho-<NUM>,<NUM>-quinodimethane; [alpha],[alpha]'-bis(dithieno[<NUM>,<NUM>-b2',<NUM>'-d]thiophene); dithieno[<NUM>,<NUM>-d;<NUM>',<NUM>'-d']benzo[<NUM>,<NUM>-b;<NUM>,<NUM>-b']dithiophene (DTBDT); poly dithienobenzodithiophene-co-diketopyrrolopyrrolebithiophene(PDPDBD); isoindigo-Bithiophene-(IIDDT-C3), thieno[<NUM>,<NUM>-b]thiophene-<NUM>-fluorobenzo[c][<NUM>,<NUM>,<NUM>]thiadiazole copolymers, di(thiophen-<NUM>-yl)thieno[<NUM>,<NUM>-b]thiophene (DTTT); <NUM>,<NUM>-dialkyl, substituted dialkyl, diaryl or substituted diaryl anthradithiophene; <NUM>,<NUM>'-bibenzo[<NUM> ,<NUM>-b:<NUM>,<NUM>-b'jdithiophene, benzothienobenzothiophene (BTBT) polymers benzodithiazole polymers, and mixtures thereof.

Preferred compounds are those from the above list and derivatives thereof which are soluble.

The OSPL is preferably produced from a composition according to the first aspect of the invention, comprising: (a1) multi-functional acrylate compound(s); (a2) high reactivity monomer(s); (b) an organic solvent; (c) a fluoro surfactant and an acrylate- and/or methacrylate-functionalised silicone surfactant, and (d) at least one photo-initiator.

The amount of multi-functional acrylate (a1) and optionally (a2) in the final layer is preferably <NUM>-<NUM>%, more preferably <NUM>-<NUM>% weight % of the final OSPL.

The organic solvent (b) is preferably substantially removed from the final OSPL, hence it preferably remains in less than <NUM> weight % of the final OSPL.

Generally, the amount of the initiator (d) used in the polymerisable composition is about <NUM> to about <NUM> weight %, preferably about <NUM> to about <NUM> weight %, most preferably about <NUM> to about <NUM> weight % of the polymerisable composition.

When used with a thin film transistor, preferably the thin film transistor is a Top Gate device. Said device preferably has improved electrical characteristics (low Vth, low Vto, low SS, low loff and high lon/off ratios). It further optionally comprises one or more of a planarisation layer, a self-assembled monolayer. Such a device is shown in <FIG>.

The OSPL disclosed herein is preferably obtainable by polymerising a composition comprising:.

The OSPL discloed herein is preferably obtainable by polymerising a composition comprising:.

Preferably, the initiator compound (d) is selected from an amine-based initiator, a thioxanone-based initiator, and combinations thereof. Preferably, the initiator compound (d) comprises a benzoate compound, a substituted thioxanone compound or a combination thereof, preferably a combination of ethyl-<NUM>-(diamino) benzoate and diethylthioxanone, or a combination of ethyl-<NUM>-(diamino) benzoate and isopropylthioxanone.

An examples of an effective OSPL formulation according to claim <NUM> is included in Table <NUM>. Also disclosed are OSPL formulations not according to the invention in Tables <NUM> and <NUM>:.

For cost and ease of fabrication, it is desirable to solution coat the OSPL onto the gate insulator, some suitable coating techniques include but is not limited to spin coating, slot-die coating or ink jet printing. However, the very low surface free energy of the perfluoropolymer (<NUM>-<NUM> < dyne/cm) means that it is preferable to modify the surface tension of the OSPL ink formulation before coating takes place.

Preferably the formulated OSPL ink has a surface tension in the range of <NUM> to <NUM> mN/m, more preferably <NUM> to <NUM> mN/m, more preferably <NUM> to <NUM> mN/m.

The OSPL composition is modified to reduce its surface tension by addition of a surfactant composition comprising a fluoropolymer surfactant and a silicone surfactant. Preferably, less than <NUM> wt % of surfactants are included in the ink composition, more preferably less than <NUM> wt. The surfactant is preferably compatible with the acrylate-based OSPL composition.

Preferred surfactants include fluorosurfactants and acrylate and/or methacrylate-functionalised silicone surfactants. Particularly preferred are non-ionic fluorosurfactants, particularly, non-ionic perfluorosurfactants.

Preferred surfactants are those having a <NUM>% solution surface tension (mN/m) in toluene of less than <NUM> mN/m, preferably less than <NUM> mN/m, preferably ≤<NUM> mN/m.

Preferably the surfactant-containing-OSPL composition is solution deposited on to the gate insulator layer and any optional solvent is removed by thermal evaporation. The resultant layer is then crosslinked.

Once the OSPL layer is in place (~<NUM>-<NUM> thick layer), a metal gate can be deposited on to it using a plasma sputter process. Testing of the resulting OTFT devices indicates that with the OSPL in place, there is zero to minimal deterioration of transistor performance after plasma exposure, therefore the OSPL has protected the OTFT from plasma-induced damage.

OSPL screening experiments were carried out using glass substrates coated with OSC/OGI onto which the OSPL was over coated and cured. Microscope slides (<NUM> × <NUM>) were cleaned, plasma etched and treated with β-phenylethyl-trichlorosilane. These were then coated with a <NUM> layer of SKL09 organic semiconductor (SKL09 ink comprises <NUM>% solids <NUM>:<NUM> wt:wt TMTES: Methoxy-PTAA in tetralin) followed by a <NUM> layer of Cytop <NUM>. The composite stack with CYTOP/OSC/ Glass was then over-coated with sputter protective layer ink formulations which were UV-cured and assessed for degree of coverage and uniformity of film. Highly crosslinked, uniform OSPL films were obtained.

The detailed experimental method is detailed below:.

The glass slides were prepared as follows:
Glass slides cut to <NUM> × <NUM> and washed with acetone for <NUM> sec followed by IPA for <NUM> sec; dried with compressed N<NUM> gas and baked at <NUM> for <NUM>. Cooled for <NUM> mins at room temperature on aluminium plate.

Plasma etched in Plasmalab PE <NUM> with <NUM> mbar base pressure, <NUM> mW power and <NUM> sccm flow rate of etch gasses (oxygen and argon). Dried with compressed N<NUM> to remove dust prior to coating. Glass treated with β-phenylethyl trichloro silane (B-PTS) solution in anhydrous toluene (<NUM> (<NUM>) of B-PETCS in <NUM> toluene). Solution flooded onto substrate, held for <NUM> minutes, spun off (<NUM> sec <NUM> rpm, stop <NUM> sec and flood with toluene, spin at <NUM> rpm ramp to <NUM> rpm while rinsing with more toluene). Heated the substrate at <NUM> for <NUM> and then cooled tot RT for <NUM>.

Dispensed <NUM> of semiconducting ink onto the substrate through a <NUM> filter to flood the whole surface. Cover with close fitting upturned bowl and spin coat using Laurell spin coater (<NUM> rpm/<NUM>/<NUM> rpms-<NUM> then at <NUM> rpm/<NUM>/<NUM> rpms-<NUM>). Bake for <NUM> minute at <NUM> and cool for <NUM> minute on an aluminium plate.

Dispensed ~ <NUM> of <NUM>% solids solution of Cytop CTL <NUM> in FC43 solvent onto the substrate. Spin coat (<NUM> rpm/<NUM>/<NUM> rpms-<NUM> then <NUM> rpm/<NUM>/<NUM> rpms-<NUM>) heat for <NUM> sec at <NUM> and <NUM> at <NUM>; cool for <NUM> minute on an aluminium plate.

Dispense organic sputter protection layer formulation (SPL <NUM>/<NUM> + optionally fluorosurfactant) onto the substrate through a <NUM> filter. Spin coat (<NUM> rpm/<NUM>/<NUM> rpms-<NUM> then <NUM> rpm/<NUM>/<NUM> rpms-<NUM>.

Expose to between <NUM> to 3000mJ/cm<NUM> UV light, i-line and then baked at <NUM> for <NUM> minute.

Film thickness was determined with a DektakXT from Bruker Nano Surfaces Division.

Surface free energy was determined using the sessile drop technique with at least three solvents using a dataphysics OCA 15EC goniometer using the Owens, Wendt, Rabel and Kaelble model.

Surface tension was determined using the pendant drop technique and a dataphysics OCA 15EC goniometer.

Record FTIR spectra (Perkin Elmer Spectrum <NUM> instrument with diamond ATR module) for the wet uncured film prior to any UV exposure and for a series of films that have been cured to varying degrees by incremental UV exposure. Accurately baseline the spectra at three points using the troughs surrounding the absorption peaks of interest. These are typically around <NUM>, <NUM> and <NUM>-<NUM> wave numbers. Measure the height of the carbonyl peak at <NUM>-<NUM> and the alkene peak at <NUM>-<NUM>. Calculate the ratio of the absorbance at <NUM>-<NUM> to the absorbance at <NUM>-<NUM> and compare with the ratio obtained for the uncured sample. Calculate the degree of cure using the following formula: <MAT>.

<FIG> depicts a top gate bottom contact (TGBC) OTFT comprising the following components:.

The process steps to fabricate TGBC OTFTs comprise patterning source and drain electrodes (<NUM>) on top of the substrate, optionally applying an electrode surface treatment (<NUM>), applying an OSC layer (<NUM>) to cover the substrate (<NUM>) and source and drain electrodes (<NUM>), applying an OGI layer (<NUM>) on top of the OSC layer (<NUM>), coating the OSPL (<NUM>) on top of the OGI layer (<NUM>), crosslinking the OSPL layer (<NUM>), applying a gate electrode (<NUM>) on top of the OSPL. A layer of photoresist (<NUM>) is deposited on top of the gate electrode (<NUM>) and patterned to provide a mask for defining the gate electrode (<NUM>). Those parts of the OSPL, OGI and OSC layers (<NUM>), (<NUM>) and (<NUM>) respectively surrounding the gate electrode (<NUM>) are optionally removed, but the OSPL is always left intact within the channel region as in <FIG>.

TGBC OTFTs in the examples described below were fabricated using the following process steps:.

OTFT characteristics were obtained by biasing the gate and drain electrodes of the transistor relative to the source electrode. All example transistors comprise a p-type organic semiconductor such that when a negative gate voltage, VG, is present holes (positive charge carriers) are accumulated at the interface between the OGI and OSC, forming a channel. A negative voltage, VD, applied to the drain electrode causes a current, ID, to flow dependent on charge carrier density, mobility, µ, channel length, L, and width, W, as described by the equation when the OTFT is biased in the linear regime (i.e. VD < VG) <MAT>.

Vth is the threshold voltage and IL is the leakage current. Ci is the capacitance per unit area of the OGI or OGI / OSPL layer beneath the gate, which determines the charge carrier density in the channel.

Electrical measurements were obtained using a Keithley <NUM> SCS parameter analyser coupled to a Wentworth S200 probe station. To measure a device in the linear regime, the drain voltage was set to -<NUM> V, and the gate voltage swept from +30V to -30V in 1V steps.

Field effect mobility was calculated according to Equation <NUM>: <MAT> where ∂ID/∂VD is the gradient of the ID - VG plot. Note that where mobility is gate voltage dependent, the value quoted is the maximum recorded in accumulation with VD < VG.

Threshold voltage, Vth, and turn-on voltage, Vto, are both extracted from the normalised drain current, NID = ID × L/W, and is defined as the gate voltage when NID = <NUM> nA (<NUM>-<NUM> A) for Vth and <NUM> pA (<NUM>-<NUM> A) for Vto.

The off current, Ioff, of the transistor is taken as the lowest current recorded during the gate voltage sweep. Ion/off is calculated by dividing the drain current at VG = - 30V by Ioff.

Permittivity of the OSPL was determined by fabricating metal - insulator - metal (MIM) capacitors. <NUM> × <NUM> arrays MIM capacitors were fabricated as outlined below:.

Thus, MIM capacitors with two layers of dielectric are formed, the first layer consisting <NUM> of thermal oxide, the second formed by the OSPL. The thickness of the OSPL is dependent on spin coating conditions and solids content of the formulation. For a two-layer capacitor the capacitance, C, is defined as the series sum of the oxide, COX, and OSPL, CSPL, capacitances: <MAT> Wherein: <MAT> And <MAT> εOX, dOX, dSPL and εSPL are the relative permittivities and thicknesses of the oxide and OSPL layers respectively, A, the area of the capacitor and ε<NUM> is the permittivity of free space.

The permittivity of the OSPL can be extracted from equations <NUM>, <NUM> and <NUM>: <MAT>.

Capacitance of each MIM device was measured at a frequency of <NUM>, <NUM> mVP-P, using an Agilent <NUM> Precision LCR meter. OSPL and oxide thicknesses were measured with a J. Woollam M2000 Variable Angle Spectroscopic Ellipsometer at wavelengths <NUM> - <NUM> and incident angles from <NUM>° - <NUM>°. Areas of each MIM device was measured using a calibrated Nikon microscope.

Claim 1:
A solution comprising at least one multi-functional acrylate, a non-acrylate organic solvent, a fluoro surfactant and an acrylate- and/or methacrylate-functionalised silicone; wherein the solution is cross-linkable,
wherein the multi-functional acrylate comprises (a1) a multi-functional acrylate compound containing a nitrogen-containing cyclic core having at least two pendant acrylate moieties, and (a2) a polyacrylate monomer having an oxy or polyoxy-alkane core.