Graphene has been widely considered a promising candidate for high-quality chemical sensors, owing to its outstanding characteristics, such as sensitive gas adsorption at room temperature, high conductivity, high flexibility, and high transparency. However, the main drawback of a graphene-based gas sensor is the necessity for external heaters due to its slow response, incomplete recovery, and low selectivity at room temperature. Conventional heating devices have limitations such as large volume, thermal safety issues, and high power consumption. Moreover, metal-based heating systems cannot be applied to transparent and flexible devices. Thus, to solve this problem, a method of supplying the thermal energy necessary for gas sensing via the self-heating of graphene by utilizing its high carrier mobility has been studied. Herein, we provide a brief review of recent studies on self-activated graphene-based gas sensors. This review also describes various strategies for the self-activation of graphene sensors and the enhancement of their sensing properties.
Yeonhoo Kim, Yong Seok Choi, Seo Yun Park, Taehoon Kim, Seung-Pyo Hong, Tae Hyung Lee, Cheon Woo Moon, Jong‐Heun Lee, Donghwa Lee, Byung Hee Hong, Ho Won Jang
Young Geun Song, Young‐Seok Shim, Jun Min Suh, Myoung‐Sub Noh, Gwang Su Kim, Kyoung Soon Choi, Beomgyun Jeong, Sangtae Kim, Ho Won Jang, Byeong‐Kwon Ju, Chong‐Yun Kang
Young Geun Song, Young‐Seok Shim, Jun Min Suh, Myoung‐Sub Noh, Gwang Su Kim, Kyoung Soon Choi, Beomgyun Jeong, Sangtae Kim, Ho Won Jang, Byeong‐Kwon Ju, Chong‐Yun Kang
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