Patent application number | Description | Published |
20110180133 | Enhanced Silicon-TCO Interface in Thin Film Silicon Solar Cells Using Nickel Nanowires - This invention provides an optically transparent electrically conductive layer with a desirable combination of low electrical sheet resistance and good optical transparency. The conductive layer comprises a multiplicity of magnetic nanostructures in a plane, aligned into a plurality of roughly parallel continuous conductive pathways, wherein the density of the magnetic nanostructures allows for substantial optical transparency of the conductive layer. The magnetic nanostructures may be nanoparticles, nanowires or compound nanowires. A method of forming the conductive layer on a substrate includes: depositing a multiplicity of magnetic nanostructures on the substrate and applying a magnetic field to form the nanostructures into a plurality of conductive pathways parallel to the surface of the substrate. The conductive layer may be used to provide an enhanced silicon to transparent conductive oxide (TCO) interface in thin film silicon solar cells. | 07-28-2011 |
20120055534 | Photovoltaic Devices with High Work-Function TCO Buffer Layers and Methods of Manufacture - Embodiments of the invention are directed to photovoltaic cells comprising a substantially optically transparent buffer layer on a superstrate and a photoabsorber layer on the buffer layer. The buffer layer of detailed embodiments has a work function greater than or equal to about the work function of the photoabsorber layer. Additional embodiments of the invention are directed to photovoltaic modules comprises a plurality of photovoltaic cells and methods of making photovoltaic cells and photovoltaic modules. | 03-08-2012 |
20120055535 | Photovoltaic Devices With Textured Glass Superstrate - Embodiments of the invention are directed to photovoltaic cells comprising a textured superstrate, a front contact layer, a photoabsorber layer and a back contact layer. The textured superstrate has a plurality of craters with an average opening angle, an average aspect ratio and an average depth. Methods of making such photovoltaic cells and photovoltaic modules are also described. | 03-08-2012 |
20120164470 | SILVER-NICKEL CORE-SHEATH NANOSTRUCTURES AND METHODS TO FABRICATE - Embodiments of the invention generally provide core-sheath nanostructures and methods for forming such nanostructures. In one embodiment, a method for forming core-sheath nanostructures includes stirring an aqueous dispersion containing silver nanostructures while adding a catalytic metal salt solution to the aqueous dispersion and forming catalytic metal coated silver nanostructures during a galvanic replacement process. The method further includes stirring an organic solvent dispersion containing the catalytic metal coated silver nanostructures dispersed in an organic solvent while adding a nickel salt solution to the organic solvent dispersion, and thereafter, adding a reducing solution to the organic solvent dispersion to form silver-nickel core-sheath nanostructures during a nickel coating process. In one embodiment, the core-sheath nanostructures are silver-nickel core-sheath nanowires, wherein each silver-nickel core-sheath nanowire has a sheath layer of nickel disposed over and encompassing a catalytic metal layer of palladium disposed on a nanowire core of silver. | 06-28-2012 |
20130095252 | METHOD AND APPARATUS FOR ALIGNING NANOWIRES DEPOSITED BY AN ELECTROSPINNING PROCESS - Embodiments of the invention generally include apparatus and methods for depositing nanowires in a predetermined pattern during an electrospinning process. An apparatus includes a nozzle for containing and ejecting a deposition material, and a voltage source coupled to the nozzle to eject the deposition material. One or more electric field shaping devices are positioned to shape the electric field adjacent to a substrate to control the trajectory of the ejected deposition material. The electric field shaping device converges an electric field at a point near the surface of the substrate to accurately deposit the deposition material on the substrate in a predetermined pattern. The methods include applying a voltage to a nozzle to eject an electrically-charged deposition material towards a substrate, and shaping one or more electric fields to control the trajectory of the electrically-charged deposition material. The deposition material is then deposited on the substrate in a predetermined pattern. | 04-18-2013 |
20130102110 | METHOD AND APPARATUS OF FORMING A CONDUCTIVE LAYER - The present invention generally includes an apparatus and process of forming a conductive layer on a surface of a host substrate, which can be directly used to form a portion of an electronic device. More specifically, one or more of the embodiments disclosed herein include a process of forming a conductive layer on a surface of a substrate using an electrospinning type deposition process. Embodiments of the conductive layer forming process described herein can be used to reduce the number of processing steps required to form the conductive layer, improve the electrical properties of the formed conductive layer and reduce the conductive layer formation process complexity over current state-of-the-art conductive layer formation techniques. Typical electronic device formation processes that can benefit from one or more of the embodiments described herein include, but are not limited to processes used to form solar cells, electronic visual display devices and touchscreen type technologies. | 04-25-2013 |
20130302595 | SUPER-HYDROPHOBIC AND OLEOPHOBIC TRANSPARENT COATINGS FOR DISPLAYS - Embodiments described herein generally relate to methods of creating super-hydrophobic and super-oleophobic layers and the resulting composition of matter. A method for creating a super-hydrophobic and super-oleophobic surface can include positioning a substrate with an exposed surface in a processing chamber, injecting an electrically charged silicon-containing deposition material towards the surface of the substrate, depositing silicon-containing nanofibers onto the exposed surface of the substrate, and depositing a thin low surface energy layer over the exposed surface of the substrate and the silicon-containing nanofibers. A substrate with a super-hydrophobic and super-oleophobic surface can include a substrate with an exposed surface, one or more layers of nanofibers disposed on the exposed surface, and a thin low surface energy material deposited over both the nanofibers and the exposed surface. | 11-14-2013 |
20140264354 | BUFFER LAYERS FOR METAL OXIDE SEMICONDUCTORS FOR TFT - The present invention generally relates to a thin film semiconductor device having a buffer layer formed between the semiconductor layer and one or more layers. In one embodiment, a thin film semiconductor device includes a semiconductor layer having a first work function and a first electron affinity level, a buffer layer having a second work function greater than the first work function and a second electron affinity level that is less than the first electron affinity level; and a gate dielectric layer having a third work function less than the second work function and a third electron affinity level that is greater than the second electron affinity level. | 09-18-2014 |