Eiji Aoyagi scite author profile

This paper reports a fast and highly sensitive all-graphene humidity sensor working in a novel alternating current (ac) detection mode for the first time, which is capable of sensing humidity on a smartphone for portable electronics. The humidity sensor is based on an interdigitated reduced graphene oxide/graphene oxide/rGO (rGO/GO/rGO) structure patterned by a facile laser direct writing method. It works in an ac sensing mode with a rectangular input voltage wave and measures the output voltage wave instead of conventional resistance, impedance, or capacitance, exhibiting a dramatically enhanced sensitivity by about 45 times compared to the low and unstable response in dc mode. The humidity sensor shows an obvious response to the relative humidity (RH) ranging from RH 6.3% to RH 100%. The response and recovery toward humidity change are almost instantaneous, and the corresponding costed times including humidity rise and decay times are less than 1.9 and 3.9 s, respectively, which are among the best results in the literature. The sensor also exhibits outstanding cycling stability, flexibility, and long-term stability (>1 year), as well as good reproducibility of device preparation. Besides, it can be easily connected to an iPhone and the humidity sensing can be conducted with an oscilloscope application on iOS. What's more, an electronic circuit simulation method was employed to fit the output waves, which can not only explain the sensing mechanism, but also determine the resistance and capacitance of the rGO/GO/rGO structure, agreeing well with the results obtained from the electrochemical measurements. It can be reasonably expected that the approach combining humidity sensing and electronic circuit simulation can be applied in real-time monitoring on a smartphone based on the Internet of things and big data technologies.

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Laser direct writing of heteroatom-doped porous carbon for high-performance micro-supercapacitors

Cai

et al. 2020

Energy Storage Materials

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High performance of thin nano-crystalline ZrN diffusion barriers in Cu/Si contact systems

Takeyama

Itoi

Aoyagi

et al. 2002

Applied Surface Science

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Low temperature deposited Zr–B film applicable to extremely thin barrier for copper interconnect

Takeyama

Noya

Yasuo

et al. 2009

Applied Surface Science

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Facile preparation of large-area self-supported porous nickel phosphide nanosheets for efficient electrocatalytic hydrogen evolution

Liu

et al. 2019

International Journal of Hydrogen Energy

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Eiji Aoyagi

Laser Direct Writing of a High-Performance All-Graphene Humidity Sensor Working in a Novel Sensing Mode for Portable Electronics

Laser direct writing of heteroatom-doped porous carbon for high-performance micro-supercapacitors

High performance of thin nano-crystalline ZrN diffusion barriers in Cu/Si contact systems

Low temperature deposited Zr–B film applicable to extremely thin barrier for copper interconnect

Facile preparation of large-area self-supported porous nickel phosphide nanosheets for efficient electrocatalytic hydrogen evolution

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