Abstract: In one aspect, optoelectronic devices are described herein. In some implementations, an optoelectronic device comprises a photovoltaic cell. The photovoltaic cell comprises a space-charge region, a quasi-neutral region, and a low bandgap absorber region (LBAR) layer or an improved transport (IT) layer at least partially positioned in the quasi-neutral region of the cell.

Abstract: A method for forming a solar cell including steps of (1) providing a semiconductor wafer having an upper surface; (2) applying an electrical contact material to the upper surface, the electrical contact material forming an electrically conductive grid that includes grid lines extending from a bus bar; (3) forming an isolation channel in the semiconductor wafer to define a solar cell portion and a wing portion, wherein the wing portion is electrically isolated from the solar cell portion, and wherein the wing portion is substantially free of the electrical contact material; (4) submerging the semiconductor wafer in a solvent, wherein formation of metal dendrites on the grid lines of the electrically conductive grid is inhibited; and (5) separating the solar cell portion from the wing portion.

Abstract: A quantum efficiency test controller (QETC) and related techniques for measuring quantum efficiency are described. The QETC performs one or more test iterations to obtain test results regarding quantum efficiency of a multijunction photovoltaic device (MPD) having a number N of photovoltaic junctions (N>0), where the QETC is associated with N bias light sources. During a test iteration, the QETC activates a grating monochromator to emit a first test probe of monochromatic light at a first wavelength; and while the grating monochromator is emitting the first test probe, iterates through and activates each of the N bias light sources to emit a corresponding bias band of wavelengths of light. After performing the test iteration(s), the QETC generates an output that is based on the test results related to the quantum efficiency of the MPD.

Abstract: A micro-concentrator solar array is provided, and includes a plurality of solar cells and a plurality of micro-electromechanical systems (MEMS) based reflectors. Each solar cell includes a focal point. The MEMS based reflectors are each selectively tiltable about at least one axis to reflect a beam of light onto the focal point of one of the solar cells.

Abstract: A low bandgap absorber region (LBAR) used in a laser power converter (LPC). The laser power converter is comprised of one or more subcells on a substrate, wherein at least one of the subcells has an emitter and base, with the low bandgap absorber region coupled between the emitter and base. The emitter and base are comprised of a material with a bandgap higher than a wavelength of incident laser light, and the low bandgap absorber region is comprised of a material with a bandgap lower than the emitter and base. The emitter and base are transparent to the incident laser light, and the low bandgap absorber region absorbs the incident laser light and generates a current in response thereto, such that the current is controlled by the material and thickness of the low bandgap absorber region. The low bandgap absorber region is configured to produce a current balanced to the subcells connected in series.

Abstract: In one aspect, optoelectronic devices are described herein. In some implementations, an optoelectronic device comprises a photovoltaic cell. The photovoltaic cell comprises a space-charge region, a quasi-neutral region, and a low bandgap absorber region (LBAR) layer or an improved transport (IT) layer at least partially positioned in the quasi-neutral region of the cell.

Abstract: In one aspect, optoelectronic devices are described herein. In some implementations, an optoelectronic device comprises a photovoltaic cell. The photovoltaic cell comprises a space-charge region, a quasi-neutral region, and a low bandgap absorber region (LBAR) layer or an improved transport (IT) layer at least partially positioned in the quasi-neutral region of the cell.

Abstract: A quantum efficiency test controller (QETC) and related techniques for measuring quantum efficiency are described. The QETC performs one or more test iterations to obtain test results regarding quantum efficiency of a multijunction photovoltaic device (MPD) having a number N of photovoltaic junctions (N>0), where the QETC is associated with N bias light sources. During a test iteration, the QETC activates a grating monochromator to emit a first test probe of monochromatic light at a first wavelength; and while the grating monochromator is emitting the first test probe, iterates through and activates each of the N bias light sources to emit a corresponding bias band of wavelengths of light. After performing the test iteration(s), the QETC generates an output that is based on the test results related to the quantum efficiency of the MPD.

Abstract: A method for forming a solar cell including steps of (1) providing a semiconductor wafer having an upper surface; (2) applying an electrical contact material to the upper surface, the electrical contact material forming an electrically conductive grid that includes grid lines extending from a bus bar; (3) forming an isolation channel in the semiconductor wafer to define a solar cell portion and a wing portion, wherein the wing portion is electrically isolated from the solar cell portion, and wherein the wing portion is substantially free of the electrical contact material; (4) submerging the semiconductor wafer in a solvent, wherein formation of metal dendrites on the grid lines of the electrically conductive grid is inhibited; and (5) separating the solar cell portion from the wing portion.

Abstract: A method and apparatus for focusing light onto a plurality of solar cells. The apparatus comprises a plurality of solar cells, a plurality of groups of reflectors corresponding to the plurality of solar cells, and a control module in communication with the plurality of solar cells and the plurality of groups of reflectors. The control module includes control logic for monitoring an electrical output from the plurality of solar cells and repositioning the plurality of groups of reflectors when the electrical output is below a selected threshold.

Abstract: A method and apparatus for calibrating a reflector in a solar array. A switch device is switched from a first state to a second state. A calibration voltage is applied to each of a set of actuation devices associated with the reflector in response to the switch device switching to the second state when the calibration circuit is electrically connected to the set of actuation devices.

Abstract: A method for forming a solar cell including steps of (1) providing a semiconductor wafer having an upper surface; (2) applying an electrical contact material to the upper surface, the electrical contact material forming an electrically conductive grid that includes grid lines extending from a bus bar; (3) forming an isolation channel in the semiconductor wafer to define a solar cell portion and a wing portion, wherein the wing portion is electrically isolated from the solar cell portion, and wherein the wing portion is substantially free of the electrical contact material; (4) submerging the semiconductor wafer in a solvent, wherein formation of metal dendrites on the grid lines of the electrically conductive grid is inhibited; and (5) separating the solar cell portion from the wing portion.

Abstract: A semiconductor device structure having increased photogenerated current density, and increased current output is disclosed. The device includes low bandgap absorber regions that increase the range of wavelengths at which photogeneration of charge carriers takes place, and for which useful current can be collected. The low bandgap absorber regions may be strain balanced by strain-compensation regions, and the low bandgap absorber regions and strain-compensation regions may be formed from the same ternary semiconductor family. The device may be a solar cell, subcell, or other optoelectronic device with a metamorphic or lattice-mismatched base layer, for which the low bandgap absorber region improves the effective bandgap combination of subcells and current balance within the multijunction cell, for higher efficiency conversion of the solar spectrum.

Abstract: A method and apparatus for managing a solar array. Light is measured using a threshold sensor to generate sensor data. A selected threshold is computed for an electrical output generated by a plurality of solar cells in the solar array based on the sensor data using control logic in a control module.

Abstract: A method for forming a solar cell including steps of (1) providing a semiconductor wafer having an upper surface; (2) applying an electrical contact material to the upper surface, the electrical contact material forming an electrically conductive grid that includes grid lines extending from a bus bar; (3) forming an isolation channel in the semiconductor wafer to define a solar cell portion and a wing portion, wherein the wing portion is electrically isolated from the solar cell portion, and wherein the wing portion is substantially free of the electrical contact material; (4) submerging the semiconductor wafer in a solvent, wherein formation of metal dendrites on the grid lines of the electrically conductive grid is inhibited; and (5) separating the solar cell portion from the wing portion.

Abstract: In one aspect, optoelectronic devices are described herein. In some implementations, an optoelectronic device comprises a photovoltaic cell. The photovoltaic cell comprises a space-charge region, a quasi-neutral region, and a low bandgap absorber region (LBAR) layer or an improved transport (IT) layer at least partially positioned in the quasi-neutral region of the cell.

Abstract: In one aspect, optoelectronic devices are described herein. In some implementations, an optoelectronic device comprises a photovoltaic cell. The photovoltaic cell comprises a space-charge region, a quasi-neutral region, and a low bandgap absorber region (LBAR) layer or an improved transport (IT) layer at least partially positioned in the quasi-neutral region of the cell.

Abstract: A method and apparatus for calibrating a reflector in a solar array. A switch device is switched from a first state to a second state. A calibration voltage is applied to each of a set of actuation devices associated with the reflector in response to the switch device switching to the second state when the calibration circuit is electrically connected to the set of actuation devices.

Abstract: A method and apparatus for managing a solar array. Light is measured using a threshold sensor to generate sensor data. A selected threshold is computed for an electrical output generated by a plurality of solar cells in the solar array based on the sensor data using control logic in a control module.

Abstract: A method and apparatus for focusing light onto a plurality of solar cells. The apparatus comprises a plurality of solar cells, a plurality of groups of reflectors corresponding to the plurality of solar cells, and a control module in communication with the plurality of solar cells and the plurality of groups of reflectors. The control module includes control logic for monitoring an electrical output from the plurality of solar cells and repositioning the plurality of groups of reflectors when the electrical output is below a selected threshold.