TY - JOUR
T1 - Impact of Lateral SnO2Nanofilm Channel Geometry on a 1024 Crossbar Chemical Sensor Array
AU - Honda, Haruka
AU - Takahashi, Tsunaki
AU - Shiiki, Yohsuke
AU - Zeng, Hao
AU - Nakamura, Kentaro
AU - Nagata, Shintaro
AU - Hosomi, Takuro
AU - Tanaka, Wataru
AU - Zhang, Guozhu
AU - Kanai, Masaki
AU - Nagashima, Kazuki
AU - Ishikuro, Hiroki
AU - Yanagida, Takeshi
N1 - Funding Information:
This work was supported by KAKENHI (Grant Numbers JP20H02208 and JP18H05243). T.T. was supported by the Japan Science and Technology Agency (JST) PRESTO Grant Number JPMJPR19M6, Japan. T.T., G.Z., K. Nagashima, and T.Y. were supported by JST CREST (Grant Number JPMJCR19I2, Japan). This work was performed under the Cooperative Research Program of the Network Joint Research Center for Materials and Devices and the Japanese Ministry of Education, Culture, Sports, Science, and Technology (MEXT) Project of the Integrated Research Consortium on Chemical Sciences.
Publisher Copyright:
© 2022 American Chemical Society. All rights reserved.
PY - 2022/2/25
Y1 - 2022/2/25
N2 - We propose a rational strategy to fabricate thermally robust, highly integrated molecular and gas sensors utilizing a lateral SnO2nanofilm channel geometry on a 1024 crossbar sensor array. The proposed lateral channel geometry substantially suppresses the detrimental effects of parasitic interconnect wire resistances compared with those of a conventional vertical sandwich-type crossbar array because of its excellent resistance controllability. A conductive oxide top-contact electrode on the lateral SnO2nanofilm channel enhances the thermal stability at temperatures of up to 500 °C in ambient air. Integrating this lateral SnO2nanofilm geometry with analog circuits enables the operation of a 1024 crossbar sensor array without selector devices to avoid sneak currents. The developed 1024 crossbar sensor array system detects the local spatial distribution of the molecular gas concentration. The spatial data of molecular concentrations include molecule-specific data to distinguish various volatile molecules based on their vapor pressures. Thus, this integrated crossbar sensor array system using lateral nanofilm geometry offers a platform for robust, reliable, highly integrated molecular and gas sensors.
AB - We propose a rational strategy to fabricate thermally robust, highly integrated molecular and gas sensors utilizing a lateral SnO2nanofilm channel geometry on a 1024 crossbar sensor array. The proposed lateral channel geometry substantially suppresses the detrimental effects of parasitic interconnect wire resistances compared with those of a conventional vertical sandwich-type crossbar array because of its excellent resistance controllability. A conductive oxide top-contact electrode on the lateral SnO2nanofilm channel enhances the thermal stability at temperatures of up to 500 °C in ambient air. Integrating this lateral SnO2nanofilm geometry with analog circuits enables the operation of a 1024 crossbar sensor array without selector devices to avoid sneak currents. The developed 1024 crossbar sensor array system detects the local spatial distribution of the molecular gas concentration. The spatial data of molecular concentrations include molecule-specific data to distinguish various volatile molecules based on their vapor pressures. Thus, this integrated crossbar sensor array system using lateral nanofilm geometry offers a platform for robust, reliable, highly integrated molecular and gas sensors.
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U2 - 10.1021/acssensors.1c02173
DO - 10.1021/acssensors.1c02173
M3 - Article
C2 - 35067043
AN - SCOPUS:85124168157
SN - 2379-3694
VL - 7
SP - 460
EP - 468
JO - ACS Sensors
JF - ACS Sensors
IS - 2
ER -