Unraveling the photoconduction characteristics of single-step synthesized CuS and Cu9S5 micro-flowers

Owing to the alteration in the fundamental properties even by a slight variation in Cu/S ratio, the Cu-S system has been complicated and its role in photoconductive devices has been rarely investigated. Herein, CuS and Cu9S5 micro-flowers have been synthesized via a single-step solvothermal process and their photoconductors have been fabricated to unveil the optoelectronic characteristics. By increasing a Cu/S ratio from CuS to Cu9S5, the reduction in bandgap from 1.60 to 1.09 eV has been observed. In addition, the impact of bandgap on conductivity under dark and light has been investigated. Under Halogen light exposure, similar to 110 times increase in the photocurrent for Cu9S5 has been observed than CuS. The detectivity and responsivity of CuS and Cu9S5 were obtained to be 9.26 x 10(5), 6.1 x 10(6) Jones and 1.37 x 10(-8), 1 x 10(-6) A/W under Halogen light. In addition, the Cu9S5 photoconductor attained maximum responsivity, 2.5 x 10(-4) A/W, and detectivity, 2.3 x 10(10) Jones at 980 nm. More importantly, the photoconduction mechanism for CuS and Cu9S5 has been studied in-depth and the role of the Cu/S ratio on the photoconductivity has been evaluated. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

The study synthesized CuS and Cu9S5 micro-flowers via a single-step solvothermal process, and investigated their photoconductors to unveil optoelectronic characteristics and the impact of bandgap on conductivity. A significant increase in photocurrent for Cu9S5 compared to CuS was observed under Halogen light exposure, leading to higher detectivity and responsivity. Additionally, Cu9S5 exhibited maximum responsivity and detectivity at 980 nm, highlighting the importance of the Cu/S ratio on photoconductivity.