Tuning the surface energetics of the BiVO₄ (010) surface: A joint computational and experimental study

Bismuth vanadate (BiVO₄) has many advantageous optoelectronic properties for water splitting that make it ideal for studying interfacial energetics. We present an integrated experimental and computational study aimed at an atomistic understanding of the interaction with water on the BiVO₄ (010) surface while varying the surface termination.

We performed first-principles calculations with Quantum Espresso (https://www.quantum-espresso.org/) and used STM, XPS, and resonant PES to elucidate the microscopic effects of varying the surface termination. Based on measured and simulated STM images, we demonstrate how surface termination may be varied to tune the photoelectrochemical performance [1]. Next, we explore how adsorbed water influences the formation of polarons using resPES. We identify structural moieties with adsorbed water that lead to the observed enhancement in the polaron signal. Finally, we compare the changes in surface energetics upon immersion in water of the BiVO₄ (010) surface with different surface terminations.

[1] D. Lee, W. Wang, C, Zhou, X. Tong, M. Liu, G. Galli, K.-S. Choi. “Modifying interfacial energetics in BiVO₄ photoanodes by surface termination.” Submitted.