Issue 27, 2020

Semiconductor-to-conductor transition in 2D copper(ii) oxide nanosheets through surface sulfur-functionalization

Abstract

Functionalization is a widely-used strategy to modulate and optimize the properties of materials towards various applications, including sensing, catalysis, and energy generation. While the influence of sulfur-functionalization of carbon materials and oxides like ZnO and TiO2 has been studied, far less research has been devoted to analyzing sulfur-functionalization of CuO and other transition metal oxide nanomaterials. Here, we report sulfur-functionalization of copper(II) oxide nanosheets synthesized by using a soft-templating procedure, with sulfur-addition based on hydrogen sulfide gas as a source. The resulting sulfur-functionalization does not change the overall crystal structure and morphology of the CuO nanosheets, but leads to a decrease in surface hydroxyl groups. Sulfur induces a semiconductor-to-conductor state transition of the CuO nanosheets, which is supported by computational modeling. The metallic transition results from shifting of the Fermi level into the valence band due to formation of Cu–S bonds on the surface of the CuO nanosheets.

Graphical abstract: Semiconductor-to-conductor transition in 2D copper(ii) oxide nanosheets through surface sulfur-functionalization

Supplementary files

Article information

Article type
Paper
Submitted
18 Mar 2020
Accepted
25 Jun 2020
First published
26 Jun 2020

Nanoscale, 2020,12, 14549-14559

Author version available

Semiconductor-to-conductor transition in 2D copper(II) oxide nanosheets through surface sulfur-functionalization

M. J. Montgomery, N. V. Sugak, K. R. Yang, J. M. Rogers, S. A. Kube, A. C. Ratinov, J. Schroers, V. S. Batista and L. D. Pfefferle, Nanoscale, 2020, 12, 14549 DOI: 10.1039/D0NR02208J

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