Ultrasensitive Detection of VOCs Using a High‐Resolution CuO/Cu2O/Ag Nanopattern Sensor

The p‐type semiconducting copper oxides (CuO and Cu2O) are promising materials for gas sensors, owing to their characteristic oxygen adsorption properties and low operation temperature. In this study, the sensing performance of a CuO‐based chemiresistor is significantly enhanced by incorporating Ag...

Full description

Saved in:
Bibliographic Details
Published in:Advanced functional materials 2019-02, Vol.29 (9), p.n/a
Main Authors: Choi, Yoon Mi, Cho, Soo‐Yeon, Jang, Doohyung, Koh, Hyung‐Jun, Choi, Junghoon, Kim, Chong‐Hyeak, Jung, Hee‐Tae
Format: Article
Language:English
Subjects:
Acetone
Copper oxides
gas sensor
Gas sensors
Grain boundaries
High aspect ratio
Materials science
metal oxide semiconductor
Metal oxide semiconductors
Nanochannels
Nanoparticles
nanopattern
noble metal decoration
Organic chemistry
Sensitivity
Sensors
Silver
VOCs
volatile organic compound
Volatile organic compounds
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The p‐type semiconducting copper oxides (CuO and Cu2O) are promising materials for gas sensors, owing to their characteristic oxygen adsorption properties and low operation temperature. In this study, the sensing performance of a CuO‐based chemiresistor is significantly enhanced by incorporating Ag nanoparticles on high‐resolution p‐type CuO/Cu2O nanopattern channels. The high‐resolution CuO/Cu2O/Ag nanochannel is fabricated using a unique top‐down nanolithographic approach. The gas response (ΔR/Ra) of the CuO/Cu2O/Ag gas sensor increases by a maximum factor of 7.3 for various volatile organic compounds compared with a pristine CuO/Cu2O gas sensor. The sensors exhibit remarkable sensitivity (ΔR/Ra = 8.04) at 125 parts per billion (ppb) for acetone analytes. As far as it is known, this is the highest sensitivity achieved for p‐type metal oxide semiconductor (MOS)‐based gas sensors compared to previous studies. Furthermore, the outstanding gas responses observed in this study are superior to the most of n‐type MOS‐based gas sensors. The high sensitivity of the sensor is attributed to i) the high resolution (≈30 nm), high aspect ratio (≈12), and ultrasmall grain boundaries (≈10 nm) of the CuO/Cu2O nanopatterns and ii) the electronic sensitization and chemical sensitization effects induced by incorporating Ag nanoparticles on the CuO/Cu2O channels. For the first time, a 10‐nm scale CuO/Cu2O/Ag nanopattern as gas‐sensing channel materials is reported. With unique top‐down nanolithographic approaches, an ideal metal oxide semiconductor–noble metal heterojunction is achieved for electronic and chemical sensitizations with fully exposed nanochannel structures. Using this, the sensors report the best CH3COCH3‐sensing performances among previously reported p‐type metal oxide semiconductor sensors.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201808319