Issue 43, 2016

A copper-based sorbent with oxygen-vacancy defects from mechanochemical reduction for carbon disulfide absorption

Abstract

This work innovatively provides an efficient method to prepare a Cu-based sorbent with oxygen-vacancy (Ovac) defects via mechanochemical reduction of CuO for CS2 absorption. Crystalline structures based on XRD measurement show that mechanical force can lead to CuO reduction and Ovac defect generation during ball milling of CuO with Mg as a reducing agent. Sulfur content measurement shows that the prepared Cu-based sorbent with Ovac defects can realize efficient CS2 absorption at 150 °C with a breakthrough sulfur capacity of 10.7 wt%. Electronic structures based on first-principles calculation show that the Ovac defects can decrease copper coordination, increase the surface energy and electron density, and reduce the band gap by forming coordinatively unsaturated Cu, which benefit the chemisorption of CS2 molecules. Cu2O with Ovac defects, the main phase for CS2 absorption in the sorbent, can grab CS2 molecules by the trapping effect of its Ovac defects with a chemisorption distance of 1.53 Å and an energy of −110.45 kJ mol−1, and offer electrons for breaking C–S bonds. This work paves a new pathway for the preparation of Cu-based sorbents with high performance for sulfur compound absorption.

Graphical abstract: A copper-based sorbent with oxygen-vacancy defects from mechanochemical reduction for carbon disulfide absorption

Supplementary files

Article information

Article type
Paper
Submitted
19 Aug 2016
Accepted
14 Oct 2016
First published
14 Oct 2016

J. Mater. Chem. A, 2016,4, 17207-17214

A copper-based sorbent with oxygen-vacancy defects from mechanochemical reduction for carbon disulfide absorption

H. Chen, S. Zhou, Z. Han, Y. Jiang, H. Yu, X. Zhou, R. Jiang, X. Liu and X. Li, J. Mater. Chem. A, 2016, 4, 17207 DOI: 10.1039/C6TA07134A

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