Physical routes for the synthesis of kesterite

T. Ratz; G. Brammertz; R. Caballero; M. León; S. Canulescu; J. Schou; L. Gütay; D. Pareek; T. Taskesen; D. H. Kim; J. K. Kang; C. Malerba; A. Redinger; E. Saucedo; B. Shin; H. Tampo; K. Timmo; N. D. Nguyen; B. Vermang

doi:10.1088/2515-7655/ab281c

Physical routes for the synthesis of kesterite

T. Ratz, G. Brammertz, R. Caballero, M. León, S. Canulescu, J. Schou, L. Gütay, D. Pareek, T. Taskesen, D. H. Kim, J. K. Kang, C. Malerba, A. Redinger, E. Saucedo, B. Shin, H. Tampo, K. Timmo, N. D. Nguyen, B. Vermang

Division of Energy Techonology

Research output: Contribution to journal › Review article › peer-review

47 Scopus citations

Abstract

This paper provides an overview of the physical vapor technologies used to synthesize Cu₂ZnSn(S,Se)₄ thin films as absorber layers for photovoltaic applications. Through the years, CZT(S,Se) thin films have been fabricated using sequential stacking or co-sputtering of precursors as well as using sequential or co-evaporation of elemental sources, leading to high-efficient solar cells. In addition, pulsed laser deposition of composite targets and monograin growth by the molten salt method were developed as alternative methods for kesterite layers deposition. This review presents the growing increase of the kesterite-based solar cell efficiencies achieved over the recent years. A historical description of the main issues limiting this efficiency and of the experimental pathways designed to prevent or limit these issues is provided and discussed as well. A final section is dedicated to the description of promising process steps aiming at further improvements of solar cell efficiency, such as alkali doping and bandgap grading.

Original language	English
Article number	042003
Journal	JPhys Energy
Volume	1
Issue number	4
DOIs	https://doi.org/10.1088/2515-7655/ab281c
State	Published - Oct 2019

Bibliographical note

Publisher Copyright:
© 2019 The Author(s). Published by IOP Publishing Ltd.

Keywords

Absorber layer
Earth-abundant materials
Kesterite
Physical vapor deposition
Thin film solar cell

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1088/2515-7655/ab281c

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Ratz, T., Brammertz, G., Caballero, R., León, M., Canulescu, S., Schou, J., Gütay, L., Pareek, D., Taskesen, T., Kim, D. H., Kang, J. K., Malerba, C., Redinger, A., Saucedo, E., Shin, B., Tampo, H., Timmo, K., Nguyen, N. D., & Vermang, B. (2019). Physical routes for the synthesis of kesterite. JPhys Energy, 1(4), Article 042003. https://doi.org/10.1088/2515-7655/ab281c

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abstract = "This paper provides an overview of the physical vapor technologies used to synthesize Cu2ZnSn(S,Se)4 thin films as absorber layers for photovoltaic applications. Through the years, CZT(S,Se) thin films have been fabricated using sequential stacking or co-sputtering of precursors as well as using sequential or co-evaporation of elemental sources, leading to high-efficient solar cells. In addition, pulsed laser deposition of composite targets and monograin growth by the molten salt method were developed as alternative methods for kesterite layers deposition. This review presents the growing increase of the kesterite-based solar cell efficiencies achieved over the recent years. A historical description of the main issues limiting this efficiency and of the experimental pathways designed to prevent or limit these issues is provided and discussed as well. A final section is dedicated to the description of promising process steps aiming at further improvements of solar cell efficiency, such as alkali doping and bandgap grading.",

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AU - Ratz, T.

AU - Brammertz, G.

AU - Caballero, R.

AU - León, M.

AU - Canulescu, S.

AU - Schou, J.

AU - Gütay, L.

AU - Pareek, D.

AU - Taskesen, T.

AU - Kim, D. H.

AU - Kang, J. K.

AU - Malerba, C.

AU - Redinger, A.

AU - Saucedo, E.

AU - Shin, B.

AU - Tampo, H.

AU - Timmo, K.

AU - Nguyen, N. D.

AU - Vermang, B.

PY - 2019/10

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N2 - This paper provides an overview of the physical vapor technologies used to synthesize Cu2ZnSn(S,Se)4 thin films as absorber layers for photovoltaic applications. Through the years, CZT(S,Se) thin films have been fabricated using sequential stacking or co-sputtering of precursors as well as using sequential or co-evaporation of elemental sources, leading to high-efficient solar cells. In addition, pulsed laser deposition of composite targets and monograin growth by the molten salt method were developed as alternative methods for kesterite layers deposition. This review presents the growing increase of the kesterite-based solar cell efficiencies achieved over the recent years. A historical description of the main issues limiting this efficiency and of the experimental pathways designed to prevent or limit these issues is provided and discussed as well. A final section is dedicated to the description of promising process steps aiming at further improvements of solar cell efficiency, such as alkali doping and bandgap grading.

AB - This paper provides an overview of the physical vapor technologies used to synthesize Cu2ZnSn(S,Se)4 thin films as absorber layers for photovoltaic applications. Through the years, CZT(S,Se) thin films have been fabricated using sequential stacking or co-sputtering of precursors as well as using sequential or co-evaporation of elemental sources, leading to high-efficient solar cells. In addition, pulsed laser deposition of composite targets and monograin growth by the molten salt method were developed as alternative methods for kesterite layers deposition. This review presents the growing increase of the kesterite-based solar cell efficiencies achieved over the recent years. A historical description of the main issues limiting this efficiency and of the experimental pathways designed to prevent or limit these issues is provided and discussed as well. A final section is dedicated to the description of promising process steps aiming at further improvements of solar cell efficiency, such as alkali doping and bandgap grading.

KW - Absorber layer

KW - Earth-abundant materials

KW - Kesterite

KW - Physical vapor deposition

KW - Thin film solar cell

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DO - 10.1088/2515-7655/ab281c

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AN - SCOPUS:85102267662

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VL - 1

JO - JPhys Energy

JF - JPhys Energy

IS - 4

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ER -

Physical routes for the synthesis of kesterite

Abstract

Bibliographical note

Keywords

UN SDGs

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