Nanodisc Decorated W-WO } Suspended Nanowire: A Highly Sensitive and Selective H2S Sensor

In this paper, we report room temperature synthesis of plasma oxidized, suspended tungsten-tungsten oxide (W-WO x ) core-shell nanowire for sensing ppb level H 2 S. The electric field modulation at the W-WO x interface of the core-shell nanowire strongly influences the sensing performance and brings...

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Published in:IEEE sensors journal 2019-03, Vol.19 (6), p.2023-2030
Main Authors: Benedict, Samatha, Bhat, Navakanta
Format: Article
Language:English
Subjects:
Core-shell nanowire
Detection
Electric fields
Hydrogen sulfide
Molding materials
nanodiscs
Nanowires
Operating temperature
Oxidation
plasma oxidation
Plasma temperature
Recovery time
Selectivity
suspended
Temperature sensors
Tungsten
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Bhat, Navakanta
description In this paper, we report room temperature synthesis of plasma oxidized, suspended tungsten-tungsten oxide (W-WO x ) core-shell nanowire for sensing ppb level H 2 S. The electric field modulation at the W-WO x interface of the core-shell nanowire strongly influences the sensing performance and brings down the operating temperature all the way down to 50 °C, compared to completely oxidized (WO x ) nanowire. The optimum interface ratio (W/WO x ) of the nanowire shows response of 90.4% (1 ppm) with six months of response stability and excellent selectivity. The limit of detection of 10 ppb with response and recovery time of 4 and 46 s, respectively, is achieved. To enhance the response further, we utilize nanostructuring on top of nanowire, using nanodiscs of 20, 50, and 100 nm diameter and 10 nm height. The nanowire with nanodiscs of 20 nm diameter shows high repeatable response of 12529% (1 ppm) at 150 °C and fast response and recovery times of 12 and 19 s with detection limit of 0.5 ppb. As we switch from unpatterned to patterned nanowire, the observed change in H 2 S sensing characteristics indicates that the core-shell nanowire behavior makes a transition from p-type to n-type. Extensive material characterization is done using UV-Vis spectroscopy, XPS, and TEM.
doi_str_mv 10.1109/JSEN.2018.2884703
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subjects Core-shell nanowire
Detection
Electric fields
Hydrogen sulfide
Molding materials
nanodiscs
Nanowires
Operating temperature
Oxidation
plasma oxidation
Plasma temperature
Recovery time
Selectivity
suspended
Temperature sensors
Tungsten
title Nanodisc Decorated W-WO } Suspended Nanowire: A Highly Sensitive and Selective H2S Sensor
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