Patent application number | Description | Published |
20100251888 | Oxygen-Ion Conducting Membrane Structure - An oxygen-ion conducting membrane structure comprising a monolithic inorganic porous support, optionally one or more porous inorganic intermediate layers, and an oxygen-ion conducting ceramic membrane. The oxygen-ion conducting hybrid membrane is useful for gas separation applications, for example O | 10-07-2010 |
20110050091 | NANO-WHISKER GROWTH AND FILMS - Methods for making tin oxide films comprising nano-whiskers comprises providing a solution comprising a tin precursor and a solvent; preparing aerosol droplets of the solution; and applying the aerosol droplets to a heated glass substrate, converting the tin chloride to tin oxide to form a tin oxide film on the glass substrate, wherein the tin oxide film comprises nano-whiskers. | 03-03-2011 |
20110094577 | CONDUCTIVE METAL OXIDE FILMS AND PHOTOVOLTAIC DEVICES - Article comprising a substrate; and a conductive metal oxide film adjacent to a surface of the substrate, wherein the conductive metal oxide film has an electron mobility (cm | 04-28-2011 |
20110114169 | DYE SENSITIZED SOLAR CELLS AND METHODS OF MAKING - Dye sensitized solar cells having conductive metal oxide layers with nano-whiskers and methods of making the dye sensitized solar cells having conductive metal oxide layers with nano-whiskers are described. The method for making a dye sensitized solar cell comprises providing a conductive metal oxide layer comprising nano-whiskers, applying a porous semi-conducting layer on the conductive metal oxide layer, applying a dye to at least a portion of the porous semi-conducting layer, and applying an electrolyte adjacent to at least a portion of the dye. | 05-19-2011 |
20120159938 | Method of Making Membrane Filter - Wall flow membrane filters, fabricated by masking a first subset of the channels at one or both ends of a honeycomb body comprising an array of open-ended through-channels separated by porous channel walls, applying a membrane-forming composition to the porous channel walls of a second subset of the channels, curing the membrane-forming composition to provide a wall-adhering fluid-permeable membrane; and then plugging the first subset of channels at a first end of the body and the second subset of channels at a second end of the body, are useful in exhaust systems of improved particulate filtration efficiency for gasoline direct injection or diesel engines. | 06-28-2012 |
20130122196 | COATING APPARATUS AND METHOD FOR FORMING A COATING LAYER ON MONOLITH SUBSTRATES - A coating apparatus includes modular interfaces and substrate receptors for accommodating various shapes and sizes of monolith substrates when coating layers are applied onto the monolith substrates. The monolith substrates are laterally surrounded by an elastically deformable sleeve that prevents lateral leakage of a vacuum out of the monolith substrate when a vacuum is applied to opposing ends of the monolith substrate, thereby eliminating needs for bulky vacuum chambers. The coating apparatus also includes valves and control apparatus that enable excess precursor liquid to be drained from monolith channels in-situ, without the use of additional spin-drying steps. Coating methods for using the coating apparatus are provided. | 05-16-2013 |
20130137010 | REACTIVE SINTERING OF CERAMIC LITHIUM-ION SOLID ELECTROLYTES - A method of forming a solid, dense, hermetic lithium-ion electrolyte membrane comprises combing an amorphous, glassy, or low melting temperature solid reactant with a refractory oxide reactant to form a mixture, casting the mixture to form a green body, and sintering the green body to form a solid membrane. The resulting electrolyte membranes can be incorporated into lithium-ion batteries. | 05-30-2013 |
20140084503 | FLAME SPRAY PYROLYSIS METHOD FOR FORMING NANOSCALE LITHIUM METAL PHOSPHATE POWDERS - A flame spray pyrolysis method for making nanoscale, lithium ion-conductive ceramic powders comprises providing a precursor solution comprising chemical precursors dissolved in an organic solvent, and spraying the precursor solution into an oxidizing flame to form a nanoscale, lithium ion-conductive ceramic powder, wherein a concentration of the chemical precursors in the solvent ranges from 1 to 20 M. The precursor solution can comprise 1-20% excess lithium with respect to a stoichiometric composition of the ceramic powder. Nominal compositions of the nanoscale, ceramic powders are Li | 03-27-2014 |