GW Quasiparticle Energies and Bandgaps of Two-Dimensional Materials Immersed in Water

Computational simulations have become of major interest to screen potential photocatalysts for optimal band edge positions which straddle the redox potentials. Unfortunately, these methods suffer from a difficulty in resolving the dynamic solvent response on the band edge positions. We have developed a computational method based on the GW approximation coupled with an implicit solvation model that solves a generalized Poisson equation (GPE), that is, GW-GPE. Using GW-GPE, we have investigated the band edge locations of (quasi) 2D materials immersed in water and found a good agreement with experimental data. We identify two contributions of the solvent effect, termed a polarization-field effect and an environmental screening effect, which are found to be highly sensitive to the atomic and charge distribution of the 2D materials. We believe that the GW-GPE scheme can pave the way to predict band edge positions in solvents, enabling design of 2D material-based photocatalysts and energy systems.

Automated summary

We have developed a computational method based on the GW approximation coupled with an implicit solvation model to investigate the band edge positions of 2D materials immersed in water. We found that the solvent effect is highly sensitive to the atomic and charge distribution of the materials.