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A Strategy to Stabilize Kesterite CZTS for High-Performance Solar Cells

Cu2ZnSnS4–x Se x (CZTS) is an important semiconductor with significant potential for applications in the next generation of solar cells. CZTS has an optimal band gap (∼1.5 eV) and contains no expensive or toxic elements. However, CZTS-based solar cells suffer from low efficiency because of poor crys...

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Published in:	Chemistry of materials 2015-04, Vol.27 (8), p.2920-2927
Main Authors:	Yu, Kuang, Carter, Emily A
Format:	Article
Language:	English
Subjects:	chalcogenides CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY defects MATERIALS SCIENCE photoabsorbers SOLAR ENERGY
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description	Cu2ZnSnS4–x Se x (CZTS) is an important semiconductor with significant potential for applications in the next generation of solar cells. CZTS has an optimal band gap (∼1.5 eV) and contains no expensive or toxic elements. However, CZTS-based solar cells suffer from low efficiency because of poor crystal quality, which is partly caused by secondary phase formation during synthesis. We use density functional theory+U calculations to systematically investigate the stabilities of three CZTS phases: kesterite, stannite, and wurtzite. In agreement with previous experiment and theory, we confirm that these three phases have very similar formation energies. This finding is consistent with the known difficulties in synthesizing pure kesterite CZTS, the phase that is desirable for photovoltaic applications. To overcome this problem, we characterize surfaces and interfaces of CZTS and are able to identify certain “beneficial surfaces” that could be exploited to potentially provide extra stability for the kesterite phase. We propose the zinc blende ZnS (001) surface as a substrate to induce formation of these beneficial surfaces and to stabilize the kesterite phase, thereby serving as an effective crystallization template for the fabrication of high-performance CZTS solar cells.
doi_str_mv	10.1021/acs.chemmater.5b00172
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CZTS has an optimal band gap (∼1.5 eV) and contains no expensive or toxic elements. However, CZTS-based solar cells suffer from low efficiency because of poor crystal quality, which is partly caused by secondary phase formation during synthesis. We use density functional theory+U calculations to systematically investigate the stabilities of three CZTS phases: kesterite, stannite, and wurtzite. In agreement with previous experiment and theory, we confirm that these three phases have very similar formation energies. This finding is consistent with the known difficulties in synthesizing pure kesterite CZTS, the phase that is desirable for photovoltaic applications. To overcome this problem, we characterize surfaces and interfaces of CZTS and are able to identify certain “beneficial surfaces” that could be exploited to potentially provide extra stability for the kesterite phase. 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source	American Chemical Society:Jisc Collections:American Chemical Society Read & Publish Agreement 2022-2024 (Reading list)
subjects	chalcogenides CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY defects MATERIALS SCIENCE photoabsorbers SOLAR ENERGY
title	A Strategy to Stabilize Kesterite CZTS for High-Performance Solar Cells
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