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A General Solution to Mitigate Water Poisoning of Oxide Chemiresistors: Bilayer Sensors with Tb 4 O 7 Overlayer
Author(s) -
Jeong SeongYong,
Moon Young Kook,
Kim Jin Koo,
Park SeiWoong,
Jo Yong Kun,
Kang Yun Chan,
Lee JongHeun
Publication year - 2021
Publication title -
advanced functional materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 6.069
H-Index - 322
eISSN - 1616-3028
pISSN - 1616-301X
DOI - 10.1002/adfm.202007895
Subject(s) - overlayer , materials science , moisture , bilayer , selectivity , oxide , chemical engineering , humidity , clathrate hydrate , nanotechnology , membrane , composite material , chemistry , organic chemistry , thermodynamics , engineering , metallurgy , biochemistry , physics , hydrate , catalysis
Abstract Water poisoning, the dependence of gas‐sensing characteristics on moisture, in oxide chemiresistors remains a long‐standing challenge. Various approaches are explored to mitigate water poisoning but they are often accompanied by significant deterioration of sensing capabilities such as gas response deterioration, gas selectivity alteration, and sensor resistance increase up to unmeasurable levels. Herein, a novel sensor design with a moisture‐blocking Tb 4 O 7 overlayer is suggested as a facile and universal strategy to remove moisture poisoning without sacrificing intrinsic sensing properties. A submicrometer‐thick coating of Tb 4 O 7 overlayer on In 2 O 3 sensors effectively eliminates the humidity dependence of the gas‐sensing characteristics without significantly altering the gas response, selectivity, and sensor resistance. Furthermore, the general validity of the water‐blocking effect using the Tb 4 O 7 overlayer is confirmed in diverse gas sensors using SnO 2 , ZnO, and Pd/SnO 2 . The negligible moisture interference of the bilayer sensor is explained in terms of the hydrophobic nature of the Tb 4 O 7 overlayer and the prevention of formation of the OH radical by the interaction between Tb 4 O 7 and In 2 O 3 . A universal solution to design diverse humidity‐independent gas sensors with different gas selectivities can open up new pathways toward building accurate and robust gas sensors with new functionalities and high‐performance artificial olfaction.

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