Processing of CuInSe2-Based Solar Cells: Characterization of Deposition Processes in Terms of Chemical Reaction Analyses. Final Report, 6 May 1995 - 31 December 1998

Abstract: This project was initiated after the Boeing Company decided to terminate its photovoltaic research and development efforts, and donated some research equipment to UF. Billy Stanbery, who was part of the Boeing team, decided then to enroll at UF to pursue a Ph.D degree. As such these events constituted a rare direct technology transfer from industry to a university. This helped to preserve more than the published legacy of the solar cell efforts at Boeing, and jump-started a comprehensive, multifaceted, and mul… Show more

“…Some of the reports demonstrated 24.6% perovskite/CuInSe 2 tandem solar cells with four-terminal configuration by integrating 18.1% efficient CuInSe 2 solar cells. , Therefore, CuInSe 2 solar cell technology demonstrates a great potential to be realized as a prospective candidate for accomplishing the transition on the way to a sustainable energy-driven future. CuInSe 2 has been widely synthesized using various vacuum-based techniques including co-evaporation, sputtering, molecular beam epitaxy, chemical vapor deposition, electron beam deposition, and pulsed laser deposition. , Since 1973, CuInSe 2 photovoltaic devices were developed and widely explored to achieve high performance, scalability, and flexibility along with reduced manufacturing costs benefiting the short energy-payback time . Even after such a long period of research and development for CuInSe 2 and its photovoltaic applications, vertical and lateral optoelectronic sensors have been underexplored.…”

Wafer-Scale, Thickness-Controlled p-CuInSe₂/n-Si Heterojunction for Self-Biased, Highly Sensitive, and Broadband Photodetectors

“…Some of the reports demonstrated 24.6% perovskite/CuInSe 2 tandem solar cells with four-terminal configuration by integrating 18.1% efficient CuInSe 2 solar cells. , Therefore, CuInSe 2 solar cell technology demonstrates a great potential to be realized as a prospective candidate for accomplishing the transition on the way to a sustainable energy-driven future. CuInSe 2 has been widely synthesized using various vacuum-based techniques including co-evaporation, sputtering, molecular beam epitaxy, chemical vapor deposition, electron beam deposition, and pulsed laser deposition. , Since 1973, CuInSe 2 photovoltaic devices were developed and widely explored to achieve high performance, scalability, and flexibility along with reduced manufacturing costs benefiting the short energy-payback time . Even after such a long period of research and development for CuInSe 2 and its photovoltaic applications, vertical and lateral optoelectronic sensors have been underexplored.…”

Wafer-Scale, Thickness-Controlled p-CuInSe₂/n-Si Heterojunction for Self-Biased, Highly Sensitive, and Broadband Photodetectors