Patent application number | Description | Published |
20140137933 | DEVICES AND METHODS FOR PROVIDING CARRIER SELECTIVE CONTACT DEVICES - Devices comprising: an absorbing medium (AM) having first and second sides; a first membrane layer (ML) having first and second sides, wherein the first side of the first ML contacts the first side of the AM; a second ML having first and second sides, wherein the first side of the second ML contacts the second side of the AM; a first contact in contact with the second side of the first ML; and a second contact in contact with the second side of the second ML, wherein a first band alignment mismatch between the first contact and the AM causes a first surface of the AM on the first side of the AM to be in inversion, and wherein a second band alignment mismatch between the second contact and the AM causes a second surface of the AM on the second side of the AM to be under accumulation. | 05-22-2014 |
20140342492 | Methods For Dual-Scale Surface Texturing - Methods for preparing a substrate surface are provided, for purposes including manufacturing a low reflectivity surface. In some aspects, the methods include providing a material comprising an etching mask on a substrate, subjecting the material to a first isotropic etching phase, and subjecting the material to a first anisotropic etching phase, thereby forming a textured surface on the material, wherein the textured surface comprises structures with dimensions in a sub-micron range. | 11-20-2014 |
20150079281 | Silica Nano/Micro-Sphere Nanolithography Method by Solvent-Controlled Spin-Coating - A method is provided for preparing an etching mask on a substrate. The method includes dispersing a plurality of particles in an aprotic suspending medium to form a suspension and spin-coating the suspension on a substrate to form an etching mask on the substrate. | 03-19-2015 |
Patent application number | Description | Published |
20090314332 | HIGH EFFICIENCY SOLAR CELL - This invention relates to a high efficiency solar cell with a novel architecture. In one embodiment, the solar cell is comprised of a high energy gap cell stack and a dichroic mirror. The high energy gap cell stack is exposed to solar light before there is any splitting of the solar light into spectral components. Each cell in the high energy gap cell stack absorbs the light with photons of energy greater than or equal to its energy gap, i.e., the blue-green to ultraviolet portion of the solar light. Each cell in the high energy gap cell stack is transparent to and transmits light with photons of energy less than its energy gap. Spectral splitting is then performed by means of the dichroic mirror on the remaining light, i.e., the light transmitted by the high energy gap cell stack. | 12-24-2009 |
20100078063 | HIGH EFFICIENCY HYBRID SOLAR CELL - This invention relates to a high efficiency hybrid solar cell preferably comprised of a static concentrator, a dichroic mirror, a first cell stack comprising two cells, the first cell being a GaInP cell and the second cell being a GaAs cell and a second cell stack comprising three cells, the first cell being a Si cell, the second cell being a GaInAsP cell and the third cell being a GaInAs cell. The dichroic mirror provides a separation of the solar light into two spectral components, one component of light with photons of energy≧E | 04-01-2010 |
20100170557 | High Efficiency Solar Cell With Surrounding Silicon Scavenger Cells - This invention relates to an improved high efficiency solar cell. The improvement comprises the addition of one or more silicon cells to surround at least a portion of the active region of the solar cell. Preferably, the silicon cells completely surround the active region of the solar cell. The silicon cells act as scavenger cells to absorb light that would otherwise not be absorbed by other components of the solar cell and to convert that energy to electricity. | 07-08-2010 |
20110061726 | HIGH EFFICIENCY SOLAR CELL - This invention relates to a high efficiency solar cell with a novel architecture. In one embodiment, the solar cell is comprised of a high energy gap cell stack and a dichroic mirror. The high energy gap cell stack is exposed to solar light before there is any splitting of the solar light into spectral components. Each cell in the high energy gap cell stack absorbs the light with photons of energy greater than or equal to its energy gap, i.e., the blue-green to ultraviolet portion of the solar light. Each cell in the high energy gap cell stack is transparent to and transmits light with photons of energy less than its energy gap. Spectral splitting is then performed by means of the dichroic mirror on the remaining light, i.e., the light transmitted by the high energy gap cell stack. | 03-17-2011 |