Title :
Graphene-Based Quantum Capacitance Wireless Vapor Sensors
Author :
Deen, David A. ; Olson, Eric J. ; Ebrish, Mona A. ; Koester, Steven J.
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Minnesota, Minneapolis, MN, USA
Abstract :
A wireless vapor sensor based on the quantum capacitance effect in graphene is demonstrated. The sensor consists of a metal-oxide-graphene variable capacitor (varactor) coupled to an inductor, creating a resonant oscillator circuit. The resonant frequency is found to shift in proportion to water vapor concentration for relative humidity (RH) values ranging from 1% to 97% with a linear frequency shift of 5.7 kHz/%RH ± 0.3 kHz/%RH. The capacitance values extracted from the wireless measurements agree with those determined from capacitance-voltage measurements, providing strong evidence that the sensing arises from the variable quantum capacitance in graphene. These results represent a new sensor transduction mechanism and pave the way for graphene quantum capacitance sensors to be studied for a wide range of chemical and biological sensing applications.
Keywords :
capacitance measurement; capacitive sensors; gas sensors; graphene; humidity measurement; humidity sensors; radiotelemetry; transducers; voltage measurement; wireless sensor networks; C; RH value; biological sensing application; capacitance-voltage measurement; chemical sensing application; graphene-based quantum capacitance wireless vapor sensor; inductor; linear frequency shift; metal-oxide-graphene variable capacitor; relative humidity value; resonant oscillator circuit; sensor transduction mechanism; varactor; water vapor concentration; wireless measurement; Graphene; Humidity; Quantum capacitance; Resonant frequency; Sensors; Varactors; Graphene; quantum capacitance; sensor; varactor; wireless;
Journal_Title :
Sensors Journal, IEEE
DOI :
10.1109/JSEN.2013.2295302
