首页 | 本学科首页   官方微博 | 高级检索  
     

基于银纳米线电极-rGO敏感材料的柔性NO2气体传感器
引用本文:李闯,李伟伟,蔡理,谢丹,刘保军,向兰,杨晓阔,董丹娜,刘嘉豪,陈亚博. 基于银纳米线电极-rGO敏感材料的柔性NO2气体传感器[J]. 物理学报, 2020, 0(5): 236-243
作者姓名:李闯  李伟伟  蔡理  谢丹  刘保军  向兰  杨晓阔  董丹娜  刘嘉豪  陈亚博
作者单位:空军工程大学基础部;清华大学微电子学研究所;空军工程大学航空机务士官学校;清华大学化学工程系
基金项目:国家自然科学基金(批准号:51672154,51774191,11405270);国家重点研发计划(批准号:2016YFA0200204);陕西省自然科学基础研究计划(批准号:2017JM6072);空军工程大学基础部预先研究项目(批准号:YNJC19070501)资助的课题~~
摘    要:使用银纳米线作为材料制备柔性叉指电极,用还原氧化石墨烯(reduced graphene oxide, rGO)作为气体敏感材料制备出柔性气体传感器,并研究其对二氧化氮气体的响应特性以及柔韧性能.实验结果表明,制备的以银纳米线作为电极的r GO气体传感器可以实现室温下对浓度为5-50 ppm (1 ppm=10^–6)的NO2气体的检测,对50 ppm的NO2的响应能够达到1.19,传感器的重复性较好,恢复率能够保持在76%以上,传感器的灵敏度是0.00281 ppm^-1,对浓度为5 ppm的NO2气体的响应时间是990 s,恢复时间是1566 s.此外,传感器在0°-45°的弯曲角度下仍表现出优异的电学特性与气体传感性能,所制备的器件具有相对稳定的导电性和较好的弯曲耐受性.

关 键 词:银纳米线  柔性电极  还原氧化石墨烯  气体传感

Flexible nitrogen dioxide gas sensor based on reduced graphene oxide sensing material using silver nanowire electrode
Li Chuang,Li Wei-Wei,Cai Li,Xie Dan,Liu Bao-Jun,Xiang Lan,Yang Xiao-Kuo,Dong Dan-Na,Liu Jia-Hao,Chen Ya-Bo. Flexible nitrogen dioxide gas sensor based on reduced graphene oxide sensing material using silver nanowire electrode[J]. Acta Physica Sinica, 2020, 0(5): 236-243
Authors:Li Chuang  Li Wei-Wei  Cai Li  Xie Dan  Liu Bao-Jun  Xiang Lan  Yang Xiao-Kuo  Dong Dan-Na  Liu Jia-Hao  Chen Ya-Bo
Affiliation:(Department of Basic Science,Air Force Engineering University,Xi’an 710051,China;Tsinghua National Laboratory for Information Science and Technology,Institute of Microelectronics,Tsinghua University,Beijing 100084,China;The First Aeronautic Institute,Air Force Engineering University,Xinyang 464000,China;Department of Chemical Engineering,Tsinghua University,Beijing 100084,China)
Abstract:In recent years, flexible gas sensors have aroused wide interest of researchers due to their enormous potential applications in wearable electronic devices. In this paper, a flexible gas sensor is prepared. We use silver nanowires as flexible interdigital electrodes for gas sensors and reduced graphene oxide as gas-sensing materials. We also study its gas sensitivity and flexibility properties such as responsiveness, recovery, and repeatability to nitrogen dioxide. The experimental results show that the silver nanowire flexible electrode and the reduced graphene oxide gas sensor prepared can detect the NO2 gas with a concentration of 5-50 ppm at room temperature. The response(Ra/Rg) of the sensor to 50 ppm NO2 is 1.19. It demonstrates high response ability and repeatability. The recovery rate can be kept above 76%. The sensitivity of the sensor is 0.00281 ppm-1. The response time and recovery time of the prepared AgNWs IDE-rGO sensor for 5 ppm NO2 gas are990 s and 1566 s, respectively. At the same time, the sensor still exhibits excellent gas sensing performance at a bending angle in range from 0° to 45°. The device has relatively stable conductivity and good bending tolerance.The sensing mechanism of the sensor can be attributed to the direct charge transfer between the reduced graphene oxide material and NO2 gas molecules. In addition, the high catalytic activity and excellent conductivity of Ag that is a common catalyst material, may also play an important role in improving the gas sensitivity of reduced graphene oxide materials. Silver nanowires, as a material for interdigital electrodes,provide excellent conductivity for device as well as support for the flexibility of device. It provides the fabricated sensor for good mechanical flexibility. And the gas-sensing performance of the AgNWs IDE-rGO sensor is mainly achieved by the use of reduced oxidized graphene material reduced by hydrazine hydrate. In summary, the silver nanowire flexible electrode and the graphene gas sensor prepared in this work are helpful in realizing the flexibility of the gas sensor. It lays a foundation for the further application of flexible gas sensors and has great application prospects in wearable electronic equipments.
Keywords:silver nanowires  flexible electrodes  reduced graphene oxide  gas sensing
本文献已被 CNKI 维普 等数据库收录!
设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号