Sensing Responses Based on Transfer Characteristics of InAs Nanowire Field-Effect Transistors

Nanowire-based field-effect transistors (FETs) have demonstrated considerable promise for a new generation of chemical and biological sensors. Indium arsenide (InAs), by virtue of its high electron mobility and intrinsic surface accumulation layer of electrons, holds properties beneficial for creati...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Switzerland), 2017-07, Vol.17 (7), p.1640
Main Authors: Tseng, Alex C, Lynall, David, Savelyev, Igor, Blumin, Marina, Wang, Shiliang, Ruda, Harry E
Format: Article
Language:English
Subjects:
Acetic acid
Acids
Adsorption
Arsenides
Charge density
Chemical sensors
Electron mobility
Field effect transistors
field-effect transistor
InAs
Indium arsenides
nanowire
Nanowires
Organic chemistry
Resistance
Semiconductor devices
sensor
Sensors
Surface charge
Surface chemistry
Transient current
Transistors
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Summary:Nanowire-based field-effect transistors (FETs) have demonstrated considerable promise for a new generation of chemical and biological sensors. Indium arsenide (InAs), by virtue of its high electron mobility and intrinsic surface accumulation layer of electrons, holds properties beneficial for creating high performance sensors that can be used in applications such as point-of-care testing for patients diagnosed with chronic diseases. Here, we propose devices based on a parallel configuration of InAs nanowires and investigate sensor responses from measurements of conductance over time and FET characteristics. The devices were tested in controlled concentrations of vapour containing acetic acid, 2-butanone and methanol. After adsorption of analyte molecules, trends in the transient current and transfer curves are correlated with the nature of the surface interaction. Specifically, we observed proportionality between acetic acid concentration and relative conductance change, off current and surface charge density extracted from subthreshold behaviour. We suggest the origin of the sensing response to acetic acid as a two-part, reversible acid-base and redox reaction between acetic acid, InAs and its native oxide that forms slow, donor-like states at the nanowire surface. We further describe a simple model that is able to distinguish the occurrence of physical versus chemical adsorption by comparing the values of the extracted surface charge density. These studies demonstrate that InAs nanowires can produce a multitude of sensor responses for the purpose of developing next generation, multi-dimensional sensor applications.
ISSN:1424-8220
1424-8220
DOI:10.3390/s17071640