Substrate controls photovoltage, photocurrent and carrier separation in nanostructured Bi2S3 films†
Abstract
Bi2S3 is a narrow bandgap (1.2 eV) semiconductor of interest for the construction of solar cells and photoelectrodes. While many researchers have reported on the use of Bi2S3 as a sensitizer for photoelectrodes, the photoelectrochemical (PEC) properties of pure Bi2S3 films are less documented. Here, phase pure Bi2S3 films (Bi/S elemental ratio of 0.66) were grown on FTO, ITO, Au, Mo substrates by electrochemical deposition of bismuth, followed by sulfurization in a single-zone tube furnace. The nanostructured Bi2S3 films are 5 ± 1 μm thick and crystallize in an orthorhombic Stibnite type structure. They have a bandgap of ∼1.24 eV based on UV-Vis diffuse reflectance and are n-type based on a negative surface photovoltage (SPV) signal. X-ray photoelectron spectroscopy (XPS) places the Fermi level at 0.95–0.91 eV above the valence band edge. According to X-ray diffraction the substrates have no influence on the crystallographic properties of the Bi2S3 films. However, the PEC properties of Bi2S3 films in 0.5 M Na2S(aq) are sensitively controlled by the Bi2S3/substrate interface. Under 100 mW cm−2 simulated solar (AM 1.5) illumination and 1.23 VRHE applied bias, Bi2S3 photoelectrodes produce anodic photocurrents of 9.3 mA cm−2, 6.1, 3.6 and 1.8 mA cm−2 for FTO, Mo, Au and ITO substrates, respectively, and photovoltages of 0.9–0.25 V. For FTO, the photocurrent reported here is among the best reported for phase pure Bi2S3 photoanodes. The lower performance of the other substrates is due to a Schottky barrier at the Bi2S3/substrate interface, which retards electron transfer. These findings explain why FTO is a preferred substrate for Bi2S3 photoanodes and they highlight the importance of matching substrate workfunction to the Bi2S3 Fermi level for efficient majority carrier extraction. Lastly, the work demonstrates the use of electrochemical deposition combined with single-zone furnace-based sulfurization as a pathway to form high-quality Bi2S3 films for solar energy conversion.