AI Article Synopsis
- Ultrathin silicon nanowires (SiNWs) are created using a cost-effective method, making them excellent components for sensitive field-effect transistor (FET) sensors.
- A high-density array of ultrathin SiNWs, measuring 24 nm in diameter and spaced only 120 nm apart, is established through a novel fabrication technique.
- The resulting FETs show impressive performance in detecting ammonia gas with a high sensitivity and rapid response, confirming their potential for advanced gas sensing applications in flexible and scalable technologies.
Article Abstract
Ultrathin silicon nanowires (SiNWs), grown via a high-yield and low-cost catalytic approach, are ideal building blocks for the construction of highly sensitive field-effect transistor (FET) sensors. In this work, we demonstrate a high-density growth integration of an ultrathin SiNW array, with diameter down to = 24 ± 3 nm and narrow NW-to-NW spacing of only 120 nm, fabricated via an in-plane solid-liquid-solid (IPSLS) approach. Junctionless bottom-gated SiNW FETs are successfully constructed, exhibiting a high on/off current ratio of >10 and a sharp subthreshold swing of 156 mV/dec These provide an excellent platform for realizing high-performance NH sensing at room temperature, with a high response of 96.9% at 25 ppm and 38.6% at 2.5 ppm, rapid response time of 7.9 s for 5% response (or 85.8 s for 50% response), and superior selectivity against common volatile organic compound gases in ambient environments. Finally, the field-effect sensing mechanism is attributed to the Schottky barrier modulation by the adsorbed NH molecules at the metal/SiNW interface, as confirmed through an epoxy-masked selective region comparative analysis. These results provide a solid basis for the ultrathin catalytic IPSLS-SiNWs to serve as advantageous one-dimensional (1D) channels for the scalable integration of various high-performance and flexible gas sensing applications.
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| http://dx.doi.org/10.1021/acssensors.4c02426 | DOI Listing |
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