12.95% Efficient Cu(In,Ga)Se₂ Solar Cells by Single-Step Atmospheric Selenization, Scaled to Monolithically Integrated Modules

Abstract: High-quality Cu(In,Ga)Se 2 (CIGS) thin-film solar cells are often prepared by a two-step process, sputtering of Cu-Ga-In precursors followed by multistep selenization, including toxic additional post-deposition treatments and complex instrumentation due to safety apprehensions. We present here a simple and relatively less toxic single-step atmospheric selenization to prepare a high-quality CIGS thin-film absorber. Solar cells made from samples by atmospheric selenization for 15 min at 550 °C without any additi… Show more

“…Between these two process, post-selenization plays a vital role in the device performance of CIGS solar cells by electrodeposition as well as the vacuum process like sputtering . Until now, one-step selenization is widely used in post-selenization because of its simple operation. − However, this selenization often causes the accumulation of gallium (Ga) near the molybdenum (Mo) layer, forms fine grains at the bottom of the CIGS films, and increases the grain boundary (GB) recombination. Furthermore, large crevices can also be found at the CIGS/Mo interface in one-step selenization, , which is detrimental for the adhesion of CIGS films on the Mo substrate and the effective collection of carriers.…”

Pulse Selenization in Cu(In,Ga)Se₂ Solar Cells: A Promising Approach to Achieve High Efficiency by Electrodeposition

“…Between these two process, post-selenization plays a vital role in the device performance of CIGS solar cells by electrodeposition as well as the vacuum process like sputtering . Until now, one-step selenization is widely used in post-selenization because of its simple operation. − However, this selenization often causes the accumulation of gallium (Ga) near the molybdenum (Mo) layer, forms fine grains at the bottom of the CIGS films, and increases the grain boundary (GB) recombination. Furthermore, large crevices can also be found at the CIGS/Mo interface in one-step selenization, , which is detrimental for the adhesion of CIGS films on the Mo substrate and the effective collection of carriers.…”

Pulse Selenization in Cu(In,Ga)Se₂ Solar Cells: A Promising Approach to Achieve High Efficiency by Electrodeposition

“…The AZO thin film with optimized conditions was validated by employing as a top electrode for copper–indium–gallium–selenide (CIGS) thin film solar cell. The device was fabricated in a AZO (900 nm)/ZnO­(40 nm)/CdS (50 nm)/CIGS (1.5 μm)/Mo (800 nm)/SLG (3 mm) substrate configuration; the other experimental details on device fabrication can be found in our previously published work . Further, AZO thin films sputtered with optimized conditions (1% oxygen flux) were post-treated at 500 °C for 30 and 60 min with an Al blanket, and the schematic is presented in Figure S1 of the Supporting Information.…”

Room Temperature Sputtered Aluminum-Doped ZnO Thin Film Transparent Electrode for Application in Solar Cells and for Low-Band-Gap Optoelectronic Devices

Monolithic Integration of Cu(In,Ga)Se2 Thin Film Solar Modules by all Nanosecond Laser Scribing