Abstract: Photovoltaic devices are formed by laser drilling vias through silicon substrates and, following surface preparation of the via sidewalls, plating a continuous, electrically conductive layer on the via sidewalls to electrically connect the emitter side of the cell with the back side of the cell. The electrically conductive layer can be formed on portions of a base emitter within the vias and on the back side of the substrate. Alternatively, the electrically conductive layer can be formed on a passivation layer on the via sidewalls and back side of the cell.

Abstract: Photovoltaic devices are formed by laser drilling vias through silicon substrates and, following surface preparation of the via sidewalls, plating a continuous, electrically conductive layer on the via sidewalls to electrically connect the emitter side of the cell with the back side of the cell. The electrically conductive layer can be formed on portions of a base emitter within the vias and on the back side of the substrate. Alternatively, the electrically conductive layer can be formed on a passivation layer on the via sidewalls and back side of the cell.

Abstract: Photovoltaic devices are formed by laser drilling vias through silicon substrates and, following surface preparation of the via sidewalls, plating a continuous, electrically conductive layer on the via sidewalls to electrically connect the emitter side of the cell with the back side of the cell. The electrically conductive layer can be formed on portions of a base emitter within the vias and on the back side of the substrate. Alternatively, the electrically conductive layer can be formed on a passivation layer on the via sidewalls and back side of the cell.

Abstract: Photovoltaic devices are formed with electroplated metal grids that are effectively adhered to the devices. Metal-rich silicides, such as nickel silicides, are formed on the devices by annealing. The metal used in the anneal exhibits low stress. Annealing may be conducted in ambient air followed by removal of oxide and excess metal from the metal-rich silicide. Laser patterning of the antireflective coating of the devices can be used to expose the emitter to form front grid contacts. Doping of the emitter in the patterned region can be increased during laser patterning. The ratio of the centerline to centerline pitch per laser width is controlled to ensure sufficient adhesion of subsequently plated busbars.

Abstract: Photovoltaic devices are formed by laser drilling vias through silicon substrates and, following surface preparation of the via sidewalls, plating a continuous, electrically conductive layer on the via sidewalls to electrically connect the emitter side of the cell with the back side of the cell. The electrically conductive layer can be formed on portions of a base emitter within the vias and on the back side of the substrate. Alternatively, the electrically conductive layer can be formed on a passivation layer on the via sidewalls and back side of the cell.

Abstract: A process for producing high performance organic thin film transistors in which the molecules in the organic thin film are highly ordered and oriented to maximize the mobility of current charge carriers. The uniform monolayer surface over various substrate materials so formed, result in a more reproducible and readily manufacturable process for higher performance organic field effect transistors that can be used to create large area circuits using a range of materials.

Abstract: A process for producing high performance organic thin film transistors in which the molecules in the organic thin film are highly ordered and oriented to maximize the mobility of current charge carriers. The uniform monolayer surface over various substrate materials so formed, result in a more reproducible and readily manufacturable process for higher performance organic field effect transistors that can be used to create large area circuits using a range of materials.

Abstract: The present invention provides a method of forming a patterned thin film on a surface of a substrate having thereon a patterned underlayer of a self-assembled monolayer. The method comprises depositing a thin film material on the self-assembled monolayer to produce a patterned thin film on the surface of the substrate. The present invention further provides processes for preparing the self-assembled monolayer. The present invention still further provides solution-based deposition processes, such as spin-coating and immersion-coating, to deposit a thin film material on the self-assembled monolayer to produce a patterned thin film on the surface of the substrate.

Abstract: A process for producing high performance organic thin film transistors in which the molecules in the organic thin film are highly ordered and oriented to maximize the mobility of current charge carriers. The uniform monolayer surface over various substrate materials so formed, result in a more reproducible and readily manufacturable process for higher performance organic field effect transistors that can be used to create large area circuits using a range of materials.

Abstract: The invention provides a device comprising an improved n-channel semiconducting film. This film consists of a perylene tetracaboxylic acid diimide compound and was deposited onto substrates by vacuum sublimation. Thin film transistor devices comprising such films as the semiconducting channel exhibit a field effect electron mobility greater than 0.01 cm2/Vs and an on/off ratio of 10000 and higher.

Abstract: The present invention provides a method of forming a patterned thin film on a surface of a substrate having thereon a patterned underlayer of a self-assembled monolayer. The method comprises depositing a thin film material on the self-assembled monolayer to produce a patterned thin film on the surface of the substrate. The present invention further provides processes for preparing the self-assembled monolayer. The present invention still further provides solution-based deposition processes, such as spin-coating and immersion-coating, to deposit a thin film material on the self-assembled monolayer to produce a patterned thin film on the surface of the substrate.

Abstract: A process for producing high performance organic thin film transistors in which the molecules in the organic thin film are highly ordered and oriented to maximize the mobility of current charge carriers. The uniform monolayer surface over various substrate materials so formed, result in a more reproducible and readily manufacturable process for higher performance organic field effect transistors that can be used to create large area circuits using a range of materials.

Abstract: The invention provides a device comprising an improved n-channel semiconducting film. This film consists of a perylene tetracaboxylic acid diimide compound and was deposited onto substrates by vacuum sublimation. Thin film transistor devices comprising such films as the semiconducting channel exhibit a field effect electron mobility greater than 0.01 cm2/Vs and an on/off ratio of 10000 and higher.

Abstract: Biobased cross-linked compositions, methods of fabrication and structures, in particular biobased printed wiring boards using the compositions and methods of making the structures are described. Biobased materials such as lignin, crop oils, wood resins, tannins, and polysaccharides and combinations thereof are cross-linked, preferably using heat, a cross-linking agent, and an initiator. The materials fabricated have suitable properties for printed wiring boards which are made by impregnating a fiberglass or biobased cloth with an admixture of the biobased material, cross-linking agent and initiator which is processed by conventional methods to produce a printed wiring board.

Abstract: An improved, aqueous base developable, high resolution photoresist composition for use in deep UV and compatable with high base strength aqueous developers is disclosed. The composition of the present invention comprises of a phenolic functional methacrylate polymer resin, a crosslinker selected from glycoluril derivatives capable of reacting with there resins under acid catalysis, a photoacid generator and an organic solvent. The composition of the present invention is particularly useful for production of negative tone images of high resolution (less than 0.125 micrometer).

Abstract: Biobased cross-linked compositions, methods of fabrication and structures, in particular biobased printed wiring boards using the compositions and methods of making the structures are described. Biobased materials such as lignin, crop oils, wood resins, tannins, and polysaccharides and combinations thereof are cross-linked, preferably using heat, a cross-linking agent, and an initiator. The materials fabricated have suitable properties for printed wiring boards which are made by impregnating a fiberglass or biobased cloth with an admixture of the biobased material, cross-linking agent and initiator which is processed by conventional methods to produce a printed wiring board.