Journal
JOURNAL OF APPLIED PHYSICS
Volume 109, Issue 1, Pages -Publisher
AMER INST PHYSICS
DOI: 10.1063/1.3525599
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Funding
- Reid and Anne Buckley Foundation for Energy and the Environment
- NSF [DMR-0955916]
- Direct For Mathematical & Physical Scien [0955916] Funding Source: National Science Foundation
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GaAsxP1-x graded buffers were grown via solid source molecular beam epitaxy (MBE) to enable the fabrication of wide-bandgap InyGa1-yP solar cells. Tensile-strained GaAsxP1-x buffers grown on GaAs using unoptimized conditions exhibited asymmetric strain relaxation along with formation of faceted trenches, 100-300 nm deep, running parallel to the [0 (1) over bar1] direction. We engineered a 6 mu m thick grading structure to minimize the faceted trench density and achieve symmetric strain relaxation while maintaining a threading dislocation density of <= 10(6) cm(-2). In comparison, compressively-strained graded GaAsxP1-x buffers on GaP showed nearly-complete strain relaxation of the top layers and no evidence of trenches but possessed threading dislocation densities that were one order of magnitude higher. We subsequently grew and fabricated wide-bandgap InyGa1-yP solar cells on our GaAsxP1-x buffers. Transmission electron microscopy measurements gave no indication of CuPt ordering. We obtained open circuit voltage as high as 1.42 V for In0.39Ga0.61P with a bandgap of 2.0 eV. Our results indicate MBE-grown InyGa1-yP is a promising material for the top junction of a future multijunction solar cell. (C) 2011 American Institute of Physics. [doi: 10.1063/1.3525599]
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