First-Principles Investigation on the Tunable Electronic Structures and Photocatalytic Properties of AlN/ScCF and GaN/ScCF Heterostructures

Overview

Journal Molecules

Publisher MDPI

Specialty Biology

Date 2024 Jul 27

PMID 39064882

Authors

Meiping Liu

Yidan Lu

Jun Song

Benyuan Ma

Kangwen Qiu

Liuyang Bai

Yinling Wang

Yuanyuan Chen

Yong Tang

Affiliations

Soon will be listed here.

Abstract

Heterostructure catalysts are highly anticipated in the field of photocatalytic water splitting. AlN/ScCF and GaN/ScCF heterostructures are proposed in this work, and the electronic structures were revealed with the first-principles method to explore their photocatalytic properties for water splitting. The results found that the thermodynamically stable AlN/ScCF and GaN/ScCF heterostructures are indirect semiconductors with reduced band gaps of 1.75 eV and 1.84 eV, respectively. These two heterostructures have been confirmed to have type-Ⅰ band alignments, with both VBM and CBM contributed to by the ScCF layer. AlN/ScCF and GaN/ScCF heterostructures exhibit the potential for photocatalytic water splitting as their VBM and CBM stride over the redox potential of water. Gibbs free energy changes in HER occurring on AlN/ScCF and GaN/ScCF heterostructures are as low as -0.31 eV and -0.59 eV, respectively. The Gibbs free energy change in HER on the AlN (GaN) layer is much lower than that on the ScCF surface, owing to the stronger adsorption of H on AlN (GaN). The AlN/ScCF and GaN/ScCF heterostructures possess significant improvements in absorption range and intensity compared to monolayered AlN, GaN, and ScCF. In addition, the band gaps, edge positions, and absorption properties of AlN/ScCF and GaN/ScCF heterostructures can be effectively tuned with strains. All the results indicate that AlN/ScCF and GaN/ScCF heterostructures are suitable catalysts for photocatalytic water splitting.

Citing Articles

Rational Design of ZnO/ScCF Heterostructure with Tunable Electronic Structure for Water Splitting: A First-Principles Study.

Tang Y, Lu Y, Ma B, Song J, Bai L, Wang Y Molecules. 2024; 29(19).

PMID: 39407568 PMC: 11477741. DOI: 10.3390/molecules29194638.

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