Economical Eco-friendly Fabrication of High Efficiency Chalcopyrite Solar Cells
Researchers in Korea achieve high power conversion efficiency using aqueous spray deposition in air environment
The power conversion efficiency (PCE) of solution-processed copper indium gallium sulfur diselenide solar cells is significantly lower compared to that achieved by expensive, vacuum-based fabrication methods. Moreover, solution-based methods rely on solvents that are hazardous. To this end, researchers at Incheon National University, Korea, have developed a cost-effective, eco-friendly fabrication technique using aqueous spray deposition in air environment that does not require vacuum. This novel approach yields a relatively high PCE of over 17%.
Clean, sustainable energy solutions are essential to meet the ever-increasing energy demands of the human population. High efficiency solar cells are promising candidates to reduce carbon emissions and achieve carbon neutrality. In this regard, solution-processed copper indium gallium sulfur diselenide solar cells (CIGSSe) solar cells have generated significant interest owing to their excellent photovoltaic properties, such as high absorption of visible light, stability, and tunable bandgap. However, large scale, practical applications are limited by a two-fold challenge. Firstly, solution-based CIGSSe fabrication yields very low power conversion efficiency and often uses solvents that are not environment-friendly. Secondly, to achieve higher power conversion efficiency, fabrication methods rely on expensive vacuum environment that leads to substantial material loss. To this end, a team of researchers led by Professor JunHo Kim from Global Energy Research Center for Carbon Neutrality, Incheon National University, Korea have developed a low-cost and eco-friendly fabrication method of high efficiency CIGSSe solar cells.
In a study made available online on 4 September 2022 and subsequently published in volume 32 Issue 46 of Advanced Functional Materials on 10 November 2022, the researchers used aqueous spray deposition in an air environment and developed a CIGSSe solar cell with power conversion efficiency (PCE) larger than 17 %. “For spray solution, we used deionized water, which is eco-friendly and cheapest solvent till date,” explains Prof. Kim. Moreover, conventional solution-based fabrication processes rely on environmentally hazardous, cadmium-based buffers for the optimization of thin-film solar cells. In this novel technique, the researchers used indium sulfide-based buffer that is a cadmium free, eco-friendly alternative.
The researchers further investigated the alloying effects of zirconium on indium sulfide buffers. Remarkably, the team found that zirconium alloying increases the electron concentration in the buffer. Moreover, this method “passivates” or reduces defect states in the CIGSSe absorber, optimizing the charge transfer between various interfaces, leading to enhanced PCE. Further, the researchers achieved even more defect passivation and higher PCE, of more than 17%, by alloying the CIGSSe absorber with potassium. The fabricated cell has an optimum bandgap for high efficiency applications such as a bottom cell or a tandem cell.
This novel technique is cost-effective and easily scalable as it does not require a vacuum environment. As Prof. Kim observes, “We carried out spray deposition in an air environment without using any high vacuum facility, which significantly reduces fabrication cost and thus makes the fabrication technique more practical and competitive in the industry sector.”
This development simultaneously improves the performance and fabrication of CIGSSe solar cells. This will revolutionize the application of these cells in integrated photovoltaic devices and vehicle integrated photovoltaic devices, and as energy sources for internet of things devices.
Authors: Md Salahuddin Mina1, SeongYeon Kim2, Temujin Enkhbat 1, Enkhjargal Enkhbayar 1, and JunHo Kim1,3
Title of original paper: High Efficiency Aqueous Solution Sprayed CIGSSe Solar Cells: Effects of Zr4+-Alloyed In2S3 Buffer and K-Alloyed CIGSSe Absorber
Journal: Advanced Functional Materials
1Nano Photoelectronic Device Lab, Department of Physics, Incheon National University, 119 Academy-ro, Yeonsu-gu, Incheon 22012, Republic of Korea
2Research Center for Thin Film Solar Cells, Daegu-Gyeongbuk Institute of Science and Technology (DGIST), Daegu 42988, Republic of Korea
3Global Energy Research Center for Carbon NeutralityIncheon National University, 119 Academy-ro, Yeonsu-gu, Incheon 22012, Republic of Korea
*Corresponding author’s email: firstname.lastname@example.org
About Incheon National University
Incheon National University (INU) is a comprehensive, student-focused university. It was founded in 1979 and given university status in 1988. One of the largest universities in South Korea, it houses nearly 14,000 students and 500 faculty members. In 2010, INU merged with Incheon City College to expand capacity and open more curricula. With its commitment to academic excellence and an unrelenting devotion to innovative research, INU offers its students real-world internship experiences. INU not only focuses on studying and learning but also strives to provide a supportive environment for students to follow their passion, grow, and, as their slogan says, be INspired.
About the author
Dr. JunHo Kim, the corresponding author of the study, is a Professor of Physics at Korea’s Incheon National University. His research group is developing high-efficiency thin-film solar cells with eco-friendly materials such as chalcopyrite, kesterite, and perovskite. He completed his PhD in Physics in 1998 at the Korea Advanced Institute of Science and Technology. Before coming to Incheon National University, he worked as a post-doctoral researcher at University of California, San Diego (1998–2000) and a research staff at the Electronics and Telecommunications Research Institute of South Korea (2000–2004).