25x Space Fresnel Lens Concentrator Using 4(+) Junction IMM Solar Cells and Nyctinastic Graphene Radiators to Mitigate LILT Effects for Outer Planet Missions, Phase I

Metadata Updated: November 12, 2020

The innovation is a unique solar array for powering NASA's deep space missions without the low-intensity, low-temperature (LILT) problems of conventional arrays. The new array uses a robust, ultra-light, color-mixing Fresnel lens to point-focus sunlight at a 25X concentration ratio onto the most advanced 4-junction and 6-junction inverted metamorphic (IMM) photovoltaic cells. Waste heat from the cells is dissipated to space by a bio-inspired nyctinastic graphene radiator. The radiator passively folds up around the cell, like a flower at night, to reduce the drastic temperature drop in deep space, due to the reduction in solar irradiance at large distances from the sun. The 25X concentration and the high-optical-efficiency lens eliminate the low-intensity (LI) problem by maintaining an irradiance on the cell of nearly one AM0 sun at 5 AU distance from the sun. The nyctinastic radiator mitigates the low-temperature (LT) problem of conventional arrays by maintaining the cell temperature at about -100 C instead of the typical -140 C at 5 AU. This warmer cell temperature minimizes changes in band gaps for the 4 junctions or 6 junctions in the cell, thereby maintaining better current matching for the series-connected junctions. The performance metrics of the new array are unprecedented. The expensive solar cells are reduced in area and cost by 95% compared to conventional one-sun cells. The cells can be heavily shielded front and back from space radiation at very low mass penalty, due to the small cell size. The overall specific power of the lens + cell assembly + radiator is more than 1,400 W/kg for a heavily shielded cell, about 3X better than for a one-sun cell with the same shielding. The feasibility of the new array technology will be proven in Phase I by the small business (Mark O'Neill, LLC), the research institution (University of Connecticut), and the IMM cell firm (SolAero). In Phase II, fully functional hardware will be developed and delivered.

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Metadata Created Date November 12, 2020
Metadata Updated Date November 12, 2020

Metadata Source

Harvested from NASA Data.json

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Resource Type Dataset
Metadata Created Date November 12, 2020
Metadata Updated Date November 12, 2020
Publisher Space Technology Mission Directorate
Unique Identifier Unknown
Identifier TECHPORT_93310
Data First Published 2018-06-01
Data Last Modified 2020-01-29
Public Access Level public
Bureau Code 026:00
Metadata Context https://project-open-data.cio.gov/v1.1/schema/catalog.jsonld
Metadata Catalog ID https://data.nasa.gov/data.json
Schema Version https://project-open-data.cio.gov/v1.1/schema
Catalog Describedby https://project-open-data.cio.gov/v1.1/schema/catalog.json
Homepage URL https://techport.nasa.gov/view/93310
Program Code 026:027
Source Datajson Identifier True
Source Hash e5e76cec9058c4122ac218531c1aadf269f7a31c
Source Schema Version 1.1

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