Barkhouse
Aaron Barkhouse, Yorktown Heights, NY US
Patent application number | Description | Published |
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20110240106 | PHOTOVOLTAIC DEVICES WITH DEPLETED HETEROJUNCTIONS AND SHELL-PASSIVATED NANOPARTICLES - Photovoltaic cells are fabricated in which the compositions of the light-absorbing layer and the electron-accepting layer are selected such that at least one side of the junction between these two layers is substantially depleted of charge carriers, i.e., both free electrons and free holes, in the absence of solar illumination. In further aspects of the invention, the light-absorbing layer is comprised of dual-shell passivated quantum dots, each having a quantum dot core with surface anions, an inner shell containing cations to passivate the core surface anions, and an outer shell to passivate the inner shell anions and anions on the core surface. | 10-06-2011 |
20110297217 | PHOTOVOLTAIC DEVICES WITH MULTIPLE JUNCTIONS SEPARATED BY A GRADED RECOMBINATION LAYER - A recombination layer with a gradient work function is provided which increases the power-conversion efficiency of multijunction photovoltaic devices by reducing the energy barrier to charge carriers migrating between pairs of photovoltaic junctions thereby facilitating the optimal recombination of opposing electron and hole currents generated when the photovoltaic is illuminated. | 12-08-2011 |
Craig Barkhouse, Redmond, WA US
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20120159256 | File System Resiliency Management - Perceived corruptions encountered on file system volumes, and which cannot be initially remedied online, are processed to verify whether they are true, existing volume data structure corruptions or, alternatively, false positives. Upon the verification of one or more of a volume's corruptions, error scanning is performed to check for, and attempt to remedy online, all the existing corruptions on the volume. Subsequent to error scanning processing, if one or more verified corruptions continue to exist on a file system volume, at file system boot up time spot corruption correction is performed to attempt to remedy the existing, verified corruptions on the volume. Spot corruption correction is performed to attempt to correct verified data structure corruptions on a volume of the file system while the volume is maintained offline for the time necessary to attempt to correct its prior identified corruptions. | 06-21-2012 |
Craig A. Barkhouse, Redmond, WA US
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20120159243 | Proactive Error Scan And Isolated Error Correction - Processing for file system volume error detection and processing for resultant error correction are separated to support system availability and user satisfaction. File system volumes for storing data structures are proactively scanned while the volumes remain online to search for errors or corruptions thereon. Found errors are scheduled to be corrected, i.e., spot corrected, dependent on the severity of the identified errors, error correction scheduling and/or at the determination of a file system administrator and/or user, to assist in maintaining minimal user and file system impact. When spot correction is initialized, one file system volume at a time is taken offline for correction. Spot correction verifies prior logged corruptions for the offline volume, and if independently verified, attempts to correct the prior noted corruptions. Volumes are retained offline only for the time necessary to verify and attempt to correct prior noted volume corruptions. | 06-21-2012 |
20120159255 | Online Fault Verification In A File System - Data structure errors, or corruptions, identified during, e.g., normal computing device system processing, file system processing or user access processing, are verified prior to the file system identifying the error for offline correction or notifying the user or system administrator a data structure error exists. Identified data structure corruptions are verified while the file system volumes are maintained online and otherwise accessible to other processing tasks and user access. Verified data structure corruptions are logged for further corrective processing. Data structure corruptions that cannot be verified, i.e., false positives, are not further processed and are not identified to file system administrators or users as corruptions, freeing the file system to concentrate on normal processing and true, verifiable errors. | 06-21-2012 |
David Aaron Randolph Barkhouse, New York, NY US
Patent application number | Description | Published |
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20130037090 | Capping Layers for Improved Crystallization - Techniques for fabrication of kesterite Cu—Zn—Sn—(Se,S) films and improved photovoltaic devices based on these films are provided. In one aspect, a method of fabricating a kesterite film having a formula Cu | 02-14-2013 |
20130269764 | Back Contact Work Function Modification for Increasing CZTSSe Thin Film Photovoltaic Efficiency - Techniques for increasing conversion efficiency of thin film photovoltaic devices through back contact work function modification are provided. In one aspect, a photovoltaic device is provided having a substrate; a back contact on the substrate, wherein at least a portion of the back contact has a work function of greater than about 4.5 electron volts; an absorber layer on a side of the back contact opposite the substrate; a buffer layer on a side of the absorber layer opposite the back contact; and a top electrode on a side of the buffer layer opposite the absorber layer. The absorber layer preferably has thickness that is less than a depletion width+an accumulation width+a carrier diffusion length. | 10-17-2013 |
David Aaron Randolph Barkhouse, Menlo Park, CA US
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20150179836 | METALLIZATION OF SOLAR CELLS - Approaches for the metallization of solar cells and the resulting solar cells are described. In an example, a method of fabricating a solar cell involves forming a barrier layer on a semiconductor region disposed in or above a substrate. The semiconductor region includes monocrystalline or polycrystalline silicon. The method also involves forming a conductive paste layer on the barrier layer. The method also involves forming a conductive layer from the conductive paste layer. The method also involves forming a contact structure for the semiconductor region of the solar cell, the contact structure including at least the conductive layer. | 06-25-2015 |