Physical routes for the synthesis of kesterite:Topical Review

Autor: Ratz, T., Brammertz, G., Caballero, R., León, M., Canulescu, Stela, 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.
Jazyk: angličtina
Rok vydání: 2019
Předmět:
Zdroj: 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 : Topical Review ', Journal of Physics: Energy, vol. 1, no. 4, 042003 . https://doi.org/10.1088/2515-7655/ab281c
DOI: 10.1088/2515-7655/ab281c
Popis: 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.
Databáze: OpenAIRE