SBIR-STTR Award

Ultra-high Efficiency Multijunction Solar Cells Using Quantum Dots
Award last edited on: 5/16/2008

Sponsored Program
SBIR
Awarding Agency
DOD : AF
Total Award Amount
$849,830
Award Phase
2
Solicitation Topic Code
AF06-274
Principal Investigator
Dennis J Flood

Company Information

NewCyte Inc

161 Forest Street
Oberlin, OH 44074
   (440) 774-2551
   djflood@newcyte.com
   www.newcyte.com
Location: Single
Congr. District: 04
County: Lorain

Phase I

Contract Number: ----------
Start Date: ----    Completed: ----
Phase I year
2006
Phase I Amount
$99,925
There is continuous pressure to improve the performance and reduce the cost of space solar arrays. However, further improvements in existing state of the art multijunction devices will likely yield only incremental improvements. Multijunction devices are currently limited by the inability to optimize the light absorption of the various layers due to the fact that materials in adjacent layers must be lattice matched, thus restricting the choices of semiconductors. We propose to dramatically increase solar cell efficiencies by developing a next generation device that incorporates quantum dot (QD) nanostructures in multijunction solar cells. The QDs will allow the optimal light absorption for the various sub-cells but will not create problems with lattice mismatches between the layers. The resulting improvements in current matching for the overall device will result in large efficiency gains. For triple junction cells we expect that efficiencies in excess of 40% will be attainable. For larger stacks, which will be much easier to fabricate than in traditional multijunction cells, efficiencies greater than 60% are predicted.

Phase II

Contract Number: ----------
Start Date: ----    Completed: ----
Phase II year
2007
Phase II Amount
$749,905
There is continuous pressure to improve the performance and reduce the cost of space solar arrays. However, further improvements in existing state of the art multijunction devices will likely yield only incremental improvements. Multijunction devices are currently limited by the inability to optimize the light absorption of the various layers due to the fact that materials in adjacent layers must be lattice matched, thus restricting the choices of semiconductors. The proposed technology as demonstrated in the Phase I program overcomes this limitation by optimizing light absorption through the incorporation of quantum dot (QD) nanostructures while maintaining traditional lattice spacings between layers allowing for high quality multilayer devices. The resulting improvements in current matching for the overall device will result in large efficiency gains. During the Phase II program, we propose triple junction cells with efficiencies of approximately 40%. For larger stacks, which will be much easier to fabricate than in traditional multijunction cells, efficiencies greater than 60% are predicted.

Keywords:
Multijunction Solar Cells, Quantum Dots, Nanostructures, Photovoltaics