| Literature DB >> 29455517 |
Hossain M Fahad1,2,3, Niharika Gupta1, Rui Han1, Sujay B Desai1,2,3, Ali Javey1,2,3.
Abstract
There is an increasing demand for mass-producible, low-power gas sensors in a wide variety of industrial and consumer applications. Here, we report chemical-sensitive field-effect-transistors (CS-FETs) based on bulk silicon wafers, wherein an electrostatically confined sub-5 nm thin charge inversion layer is modulated by chemical exposure to achieve a high-sensitivity gas-sensing platform. Using hydrogen sensing as a "litmus" test, we demonstrate large sensor responses (>1000%) to 0.5% H2 gas, with fast response (<60 s) and recovery times (<120 s) at room temperature and low power (<50 μW). On the basis of these performance metrics as well as standardized benchmarking, we show that bulk silicon CS-FETs offer similar or better sensing performance compared to emerging nanostructures semiconductors while providing a highly scalable and manufacturable platform.Entities:
Keywords: CMOS gas sensors; CS-FET; charge inversion layer; electrostatic confinement; low power; tunable sensitivity
Year: 2018 PMID: 29455517 DOI: 10.1021/acsnano.8b00580
Source DB: PubMed Journal: ACS Nano ISSN: 1936-0851 Impact factor: 15.881