Room-Temperature H₂ Gas Sensing Characterization of Graphene-Doped Porous Silicon via a Facile Solution Dropping Method.

Nu Si A Eom Hong-Baek Cho Yoseb Song Woojin Lee Tohru Sekino Yong-Ho Choa

Sensors (Basel)

Department of Fusion Chemical Engineering, Hanyang University, Ansan 15588, Korea.

Published: November 2017

In this study, a graphene-doped porous silicon (G-doped/p-Si) substrate for low ppm H₂ gas detection by an inexpensive synthesis route was proposed as a potential noble graphene-based gas sensor material, and to understand the sensing mechanism. The G-doped/p-Si gas sensor was synthesized by a simple capillary force-assisted solution dropping method on p-Si substrates, whose porosity was generated through an electrochemical etching process. G-doped/p-Si was fabricated with various graphene concentrations and exploited as a H₂ sensor that was operated at room temperature. The sensing mechanism of the sensor with/without graphene decoration on p-Si was proposed to elucidate the synergetic gas sensing effect that is generated from the interface between the graphene and p-type silicon.

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http://www.ncbi.nlm.nih.gov/pmc/articles/PMC5751383	PMC
http://dx.doi.org/10.3390/s17122750	DOI Listing

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