Enhanced sensitivity of zero-bias-operated MXene chemiresistive sensor via lignin hybridization

IF 10.7 Q1 CHEMISTRY, PHYSICAL

EcoMat Pub Date : 2024-05-07 DOI:10.1002/eom2.12453

I Ketut Gary Devara, Mi Ji Kwon, Su-Yeon Cho, Dong-Jun Kwon, Jun Hong Park

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Abstract

As global urbanization intensifies, there is an increasing need for highly sensitive and accurate environmental monitoring devices that can meet the demands of specific gas sensing applications with low power consumption. This study focuses on enhancing the sensitivity of MXene-based chemiresistive sensors for detecting CO_2(g) and NO_2(g) under zero-bias operation. This study shows that lignin hybridization effectively improves the sensitivity of a Ti₃C₂T_x MXene-based chemiresistive sensor; under zero-bias operation, lignin hybridization increases the sensitivity to 15 ppm NO_2(g) and CO_2(g) by 157.38% and 297.95%, respectively. When deposited on a flexible substrate, the MXene/lignin flexible sensor shows a similar response and sensitivity to 15 ppm NO_2(g) and CO_2(g) under 38° curvature compared to the planar sensor. Consequently, the MXene/lignin hybrid sensor is attractive for room temperature and zero-bias NO_2(g) and CO_2(g) detection. The MXene/lignin flexible sensor serves as a model system for advanced solid-state sensory platforms suitable for curved structures.

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通过木质素杂交提高零偏压操作 MXene 化学电阻传感器的灵敏度

随着全球城市化进程的加剧，人们越来越需要高灵敏度和精确的环境监测设备，以满足特定气体传感应用对低功耗的要求。本研究的重点是提高基于 MXene 的化学电阻传感器在零偏压工作条件下检测 CO2(g) 和 NO2(g) 的灵敏度。研究表明，木质素杂化可有效提高 Ti3C2Tx MXene 基化学电阻传感器的灵敏度；在零偏置工作条件下，木质素杂化可将 15 ppm NO2(g) 和 CO2(g) 的灵敏度分别提高 157.38% 和 297.95%。当沉积在柔性基底上时，与平面传感器相比，MXene/木质素柔性传感器在 38° 曲度下对 15 ppm NO2(g) 和 CO2(g) 的响应和灵敏度相似。因此，MXene/木质素混合传感器在室温零偏差检测二氧化氮（g）和二氧化碳（g）方面具有吸引力。MXene/lignin 柔性传感器可作为适用于曲面结构的先进固态传感平台的模型系统。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

EcoMat

CiteScore

17.30

自引率

0.00%

发文量

审稿时长

4 weeks