Photovoltaic (PV), a sustainable and renewable source of energy, is the best alternative to suppress the emission of greenhouse gases and limit global warming. The cost of PV systems is dropping continuously, and their energy generation price is not affected by future fuel price increases
Among different thin-film PV technologies, the compound semiconductors of the family I-III-VI2, Cu(In,Ga)Se2 (CIGS), exhibit higher power conversion efficiency. CIGS is a polycrystalline direct bandgap material with tunable bandgap between 1.04eV and 1.68eV (depending on gallium concentration), a high absorption coefficient in the visible spectrum, a thin absorber thickness that is 1/100 of that of silicon (Si) solar cells, and excellent radiation hardness. In comparison to Si solar cells (which dominate the present market), they are lighter, significantly cheaper to produce, and can be made flexible. Therefore, I proposed to develop high-efficiency, flexible single-junction CIGS solar cells using the innovative combination of pulsed hybrid reactive magnetron sputtering (PHRMS) and laser pulses.
PHRMS is a world-unique, single-step deposition process in which the amount of selenium (Se) in the deposition chamber is precisely controlled, while simultaneously sputtering a Cu-In-Ga thin film. Additionally, with controlled Se pulses, the atomic mobility of anion and cation species was promoted to enhance phase transformation.