Affiliation:
1. School of Engineering Science Simon Fraser University Burnaby British Columbia V5A 1S6 Canada
2. Department of Physics and MonArk NSF Quantum Foundry Montana State University Bozeman MT 59717 USA
3. School of Science and Technology University of New England Armidale New South Wales 2351 Australia
4. Department of Physics Simon Fraser University Burnaby British Columbia V5A 1S6 Canada
5. Faculty of Engineering Sri Lanka Institute of Information Technology New Kandy Road Malabe 10115 Sri Lanka
Abstract
AbstractVolatile organic compound (VOC) sensors have a broad range of applications including healthcare monitoring, product quality control, and air quality management. However, many such applications are demanding, requiring sensors with high sensitivity and selectivity. 2D materials are extensively used in many VOC sensing devices due to their large surface‐to‐volume ratio and fascinating electronic properties. These properties, along with their exceptional flexibility, low power consumption, room‐temperature operation, chemical functionalization potential, and defect engineering capabilities, make 2D materials ideal for high‐performance VOC sensing. Here, a 2D MoS2/Te heterojunction is reported that significantly improves the VOC detection compared to MoS2 and Te sensors on their own. Density functional theory (DFT) analysis shows that the MoS2/Te heterojunction significantly enhances the adsorption energy and therefore sensing sensitivity of the sensor. The sensor response, which denotes the percentage change in the sensor's conductance upon VOC exposure, is further enhanced under photo‐illumination and zero‐bias conditions to values up to ≈7000% when exposed to butanone. The MoS2/Te heterojunction is therefore a promising device architecture for portable and wearable sensing applications.
Funder
WorkSafeBC
British Columbia Knowledge Development Fund
Canada Foundation for Innovation
Western Economic Diversification Canada
Natural Sciences and Engineering Research Council of Canada