2014
DOI: 10.1038/ncomms5376
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Graphene nanoelectronic heterodyne sensor for rapid and sensitive vapour detection

Abstract: Nearly all existing nanoelectronic sensors are based on charge detection, where molecular binding changes the charge density of the sensor and leads to sensing signal. However, intrinsically slow dynamics of interface-trapped charges and defect-mediated charge-transfer processes significantly limit those sensors' response to tens to hundreds of seconds, which has long been known as a bottleneck for studying the dynamics of molecule-nanomaterial interaction and for many applications requiring rapid and sensitiv… Show more

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Cited by 174 publications
(151 citation statements)
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“…[29] It is now widely accepted that clean graphene should be inert to the presence of most of the gas molecules, although it is possible to amplify the more subtle dipole moment of a charge neutral gas molecule by switching it and mixing the modulated dipole signal in a high frequency setup for detection. [179] The previous observed sensitive responses of pristine graphene to gas molecules could be, therefore, ascribed to defective sensitivities, due to possible defects or polymer contaminations introduced during device fabrication. The edge of graphene, also plays a crucial role in the determination of its physical, electronic and chemical properties and thus in the sensing properties.…”
Section: Gfet Gas and Ion Sensorsmentioning
confidence: 99%
“…[29] It is now widely accepted that clean graphene should be inert to the presence of most of the gas molecules, although it is possible to amplify the more subtle dipole moment of a charge neutral gas molecule by switching it and mixing the modulated dipole signal in a high frequency setup for detection. [179] The previous observed sensitive responses of pristine graphene to gas molecules could be, therefore, ascribed to defective sensitivities, due to possible defects or polymer contaminations introduced during device fabrication. The edge of graphene, also plays a crucial role in the determination of its physical, electronic and chemical properties and thus in the sensing properties.…”
Section: Gfet Gas and Ion Sensorsmentioning
confidence: 99%
“…The tunability of the physical properties of these nanomaterials is one of the promising features for their implementation as versatile sensing platforms 72,73 . Indeed, graphene-based physical sensors have been demonstrated in many applications in recent years, including the detection and monitoring of humidity 74 , pH 75 , chemicals 76,77 , biomolecules 73,[78][79][80] , and mechanical forces [81][82][83] . Moreover, the biocompatibility of graphene opens up further possibilities for its use as a fundamental element of implantable biophysical sensors.…”
Section: Flexible and Stretchable Sensor Materials And Fabrication Sementioning
confidence: 99%
“…The detection limit of the WN/WO 3 composites sensor for NO 2 is calculated to be approximately 1.28 ppb based on signal-to-noise ratio of 3 (see the Section "Calculation of Theoretical Limit of Detection Using Signal/Noise Ratio" in Supplementary Materials), which is far below the immediately dangerous to life or health (IDLH) values (NO 2 : 20 ppm) defined by the U.S. National Institute for Occupational Safety and Health (NIOSH). The recommended NO 2 exposure limit defined by the NIOSH is 1 ppm [31]. …”
Section: Gas Sensing Characteristicsmentioning
confidence: 99%