Extending the colloidal transition metal dichalcogenide library to ReS2 nanosheets for application in gas sensing and electrocatalysis

TL;DR

This paper introduces a cost-effective colloidal synthesis method for ReS2 nanosheets, enabling scalable production for gas sensing and electrocatalysis with performance comparable to traditional methods.

Contribution

The study develops a novel colloidal synthesis approach for ReS2, reducing production costs and complexity while maintaining high performance in sensing and catalytic applications.

Findings

Colloidal ReS2 nanosheets are effective in gas sensing of toxic gases and moisture.

ReS2 nanosheet electrodes show competitive electrocatalytic activity for H2 production.

The method enables scalable and cost-efficient ReS2 fabrication for practical applications.

Abstract

Among the large family of transition metal dichalcogenides (TMDCs), recently ReS2 has stood out due to its nearly layer-independent optoelectronic and physicochemical properties. These are related to its 1T distorted octahedral structure, which leads to strong in-plane anisotropy and the presence of active sites at its surface, which makes ReS2 interesting for applications such as gas sensors and catalysts for H2 production. However, the current fabrication methods for ReS2 use chemical or physical vapor deposition (CVD or PVD) processes that are costly and involve complex and lengthy fabrication procedures, therefore limiting their large-scale production and exploitation. To address this issue, we developed a colloidal synthesis approach, which allows the production of ReS2 to be attained at temperatures below 360 Celsius degrees and with reaction times < 2 h, resulting in a more cost-efficient strategy than the CVD and PVD methods. By combining the solution-based synthesis with surface functionalization strategies, we demonstrate the feasibility of colloidal ReS2 nanosheet films for gas sensing of different toxic gases, moisture and other volatile compounds with highly competitive performance in comparison with devices built with CVD-grown ReS2 and MoS2. In addition, the integration of the ReS2 nanosheet films in assemblies, in which they are deposited on top of networks of carbon nanotubes, allowed us to fabricate electrodes for electrocatalysis for H2 production in both acid and alkaline conditions. Results from proof-of-principle devices show an electrocatalytic overpotential that is competitive with devices based on ReS2 produced by CVD, and even with MoS2, WS2 and MoSe2 electrocatalysts.