Effect of CZTS/CdS interfaces deposited with sputtering and CBD methods on Voc deficit and efficiency of CZTS solar cells

The mechanism of VOC deficit in CZTS solar cell has been systematically investigated by depositing the CdS buffer layer with sputtering (SP) and chemical bath deposition (CBD), respectively. It was found that SP-CdS film exhibits larger crystallite size and more densely packed morphology than CBD-Cd...

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Bibliographic Details
Published in:Journal of alloys and compounds 2020-03, Vol.817, p.153329, Article 153329
Main Authors: Ma, Chuanhe, Lu, Xiaoshuang, Xu, Bin, Zhao, Fei, An, Xueer, Li, Bo, Yue, Fangyu, Jiang, Jinchun, Chen, Ye, Sun, Lin, Chu, Junhao
Format: Article
Language:English
Subjects:
Antireflection coatings
Buffer layers
Cadmium sulfide
CBD method
CdS
Copper
Crystallites
Cu2ZnSnS4 solar cells
Efficiency
Energy conversion efficiency
Grain boundaries
Magnesium fluorides
Morphology
Organic chemistry
Photovoltaic cells
Solar cells
Sputtering
Sputtering method
Tin
Voc deficit
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Summary:The mechanism of VOC deficit in CZTS solar cell has been systematically investigated by depositing the CdS buffer layer with sputtering (SP) and chemical bath deposition (CBD), respectively. It was found that SP-CdS film exhibits larger crystallite size and more densely packed morphology than CBD-CdS film. The average optical transmittance of SP-CdS films deposited at 250 °C is 71.5% (74.6% at 450 °C), evidently higher than 50.2% of CBD-CdS film at 70 °C. However, CZTS solar cell with CBD-CdS shows less Voc deficit and higher conversion efficiency. By virtue of Hall and TEM measurements, the mechanism is further revealed: i) CdS can diffuse into CZTS layer easily and form a shallow n-type layer by CBD method. ii) CBD-CdS possesses high resistivity and tends to form colloidal, which can block pin-holes and type I voids between the grain boundaries. All of them improve the CZTS/CdS interface and raise the value of Rsh, and reduce the Voc deficit and boost the conversion efficiency. By optimizing the stoichiometric ratio of Cu/Sn and Zn/Sn, the best conversion efficiency of CZTS solar cells with CBD-CdS is beyond 8.2% (active area) without MgF2 anti-reflection coating. •CZTS solar cell with CBD-CdS shows less Voc deficit than that with SP-CdS.•But SP-CdS film exhibits better crystallinity and transmittance than CBD-CdS.•CBD-CdS is easier to diffuse into CZTS layer and tends to block pin-holes.•The η of pure sulfurized CZTS solar cell achieve to 8.2% (effective area).
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2019.153329