Patent application number | Description | Published |
20080206559 | LUBRICANT ENHANCED NANOCOMPOSITES - Strings configured for use in sports racquets and musical instruments are fabricated as a plastic core wrapped with one or more filaments of plastic. The strings are coated with a material composite that includes rigid nanoparticles, and lubricated nylon. The rigid nanoparticles may include clay or carbon nanotubes. The strings are coated with the material composite using various processes that result in a coating thickness of between 0.1 and 200 μm. The material composite may further include impact modifiers. The strings experience extended life due to reduced frictional wear and improved mechanical properties. | 08-28-2008 |
20080286488 | METALLIC INK - Forming a conductive film comprising depositing a non-conductive film on a surface of a substrate, wherein the film contains a plurality of copper nanoparticles and exposing at least a portion of the film to light to make the exposed portion conductive. Exposing of the film to light photosinters or fuses the copper nanoparticles. | 11-20-2008 |
20090133474 | METHOD AND APPARATUS FOR SENSING HYDROGEN GAS - A hydrogen sensor and/or switch fabricated from an array of nanowires or a nanoparticle thick film composed of metal or metal alloys. The sensor and/or switch demonstrates a wide operating temperature range and shortened response time due to fabrication materials and methods. The nanowires or nanoparticle thick films demonstrate an increase in conductivity in the presence of hydrogen. | 05-28-2009 |
20090242854 | ADDITIVES AND MODIFIERS FOR SOLVENT- AND WATER-BASED METALLIC CONDUCTIVE INKS - A conductive ink includes metallic nanoparticles, a polymeric dispersant, and a solvent. The polymeric dispersant may be ionic, non-ionic, or any combination of ionic and non-ionic polymeric dispersants. The solvent may include water, an organic solvent, or any combination thereof. The conductive ink may include a stabilizing agent, an adhesion promoter, a surface tension modifier, a defoaming agent, a leveling additive, a rheology modifier, a wetting agent, an ionic strength modifier, or any combination thereof. | 10-01-2009 |
20090274833 | METALLIC INK - A metallic ink including a vehicle, a multiplicity of copper nanoparticles, and an alcohol. The conductive metallic ink may be deposited on a substrate by methods including inkjet printing and draw-down printing. The ink may be pre-cured and cured to form a conductor on the substrate. | 11-05-2009 |
20090311440 | PHOTO-CURING PROCESS FOR METALLIC INKS - A solution of metal ink is mixed and then printed or dispensed onto the substrate using the dispenser. The film then is dried to eliminate water or solvents. In some cases, a thermal curing step can be introduced subsequent to dispensing the film and prior to the photo-curing step. The substrate and deposited film can be cured using an oven or by placing the substrate on the surface of a heater, such as a hot plate. Following the drying and/or thermal curing step, a laser beam or focused light from the light source is directed onto the surface of the film in a process known as direct writing. The light serves to photo-cure the film such that it has low resistivity. | 12-17-2009 |
20110217809 | INKS AND PASTES FOR SOLAR CELL FABRICATON - A silicon solar cell is formed with an N-type silicon layer on a P-type silicon semiconductor substrate. An antireflective and passivation layer is deposited on the N-type silicon layer, and then an aluminum ink composition is printed on the back of the silicon wafer to form the back contact electrode. The back contact electrode is sintered to produce an ohmic contact between the electrode and the P-type silicon layer. The aluminum ink composition may include aluminum powders, a vehicle, an inorganic polymer, and a dispersant. Other electrodes on the solar cell can be produced in a similar manner with the aluminum ink composition. | 09-08-2011 |
20110300305 | MECHANICAL SINTERING OF NANOPARTICLE INKS AND POWDERS - Nanoparticle inks and powders are sintered using an applied mechanical energy, such as uniaxial pressure, hydrostatic pressure, and ultrasonic energy, which may also include applying a sheer force to the inks or powders in order to make the resultant film or line conductive. | 12-08-2011 |
20120128878 | Nano-Filler for Composites - A hybrid carbon nanotube and clay nanofiller is produced by a freeze-drying process performed on clay platelets, and carbon nanotubes grown on the clay platelets using a chemical vapor deposition process. | 05-24-2012 |
20120142140 | NANOPARTICLE INKS FOR SOLAR CELLS - In a process for producing a solar cell, a sintering process performed on a nickel nanoparticle ink forms nickel silicide to create good adhesion and a low electrical ohmic contact to a silicon layer underneath, and allows for a subsequently electroplated metal layer to reduce electrode resistances. The printed nickel nanoparticles react with the silicon nitride of the antireflective layer to form conductive nickel silicide. | 06-07-2012 |
20120288991 | BURNTHROUGH FORMULATIONS - For solar cell fabrication, the addition of precursors to printable media to assist etching through silicon nitride or silicon oxide layer thus affording contact with the substance underneath the nitride or oxide layer. The etching mechanism may be by molten ceramics formed in situ, fluoride-based etching, as well as a combination of the two. | 11-15-2012 |
20130017647 | SURFACE-MODIFIED NANOPARTICLE INK FOR PHOTOVOLTAIC APPLICATIONS - Described herein is a novel material that easily penetrates silicon nitride-based anti-reflective coatings, forming a high quality electrical contact. A method for metallization on a solar cell includes depositing a passivation layer on a silicon substrate of a solar cell, depositing derivatized metal particles onto the passive layer, heating the substrate of the solar cell to migrate surface coatings from the derivatized metal particles onto the passivation layer creating a diffusion Channel through passivation layer to the silicon substrate, and as the metal particles melt due to the heating on the substrate, the melted metal diffuses through the diffusion channel forming a metallic content with the silicon substrate. | 01-17-2013 |
20140335651 | INKS AND PASTES FOR SOLAR CELL FABRICATION - A silicon solar cell is formed with an N-type silicon layer on a P-type silicon semiconductor substrate. An aluminum ink composition is printed on the back of the silicon wafer to form back contact electrodes. The back contact electrodes are sintered to produce an ohmic contact between the electrodes and the silicon layers. The aluminum ink composition may include aluminum powders, a vehicle, an inorganic polymer, and a dispersant. Other electrodes on the solar cell can be produced in a similar manner with the aluminum ink composition. | 11-13-2014 |