为研究p型材料和n型材料复合时气敏特性的变化,采用静电纺丝法分别制备了CuO、SnO2以及3种比例混合的CuO/SnO2复合纳米纤维材料,并通过XRD及SEM对其形貌、微观结构等进行表征。测试了该5种材料对丙酮、甲醛、甲醇、乙醇、甲苯等VOC气体的敏感特性。研究表明,CuO/SnO2=2∶1的复合材料对丙酮、甲苯和乙醇的的响应值有一定提高;CuO/SnO2=1∶1的复合材料对丙酮具有很高响应的同时,对乙醇和甲苯的响应产生了一定的抑制作用,从而大大提高了材料的选择性。其机理是:半导体材料复合后,在复合材料的表面会有更多的氧吸附,导致更多的VOC气体在半导体材料表面发生反应,使材料的电阻值变化更加明显,提高了材料的响应值。
In order to study the change of the gas sensitive properties when the p-type and n-type material are composited, CuO, SnO2 and CuO/SnO2 composite nanofibers materials mixed by 3 kinds proportion are prepared by using the electrospinning. The morphology, microstructure of the as-prepared materials is characterized by XRD and SEM. At the same time, the sensitivity of the 5 materials to acetone, formaldehyde, methanol, ethanol, toluene and other VOC gases was tested. The results indicate that the response values for acetone, toluene and ethanol are greatly improved when the composite proportion CuO/SnO2 is 2∶1. The response value increases from 2.8 to 4.67, from 2.2 to 3.88 and from 2.93 to 3.61 separately. With a high response to acetone with CuO/SnO2 of 1∶1 and inhibiting effect to toluene and ethanol was caused to make a good selectivity of the material. The mechanism may be that, when different materials are composited, more oxygen will be adsorbed at the surface of the materials and more VOC gases will be reacted at the surface of the semiconductor material, which make the material resistance more sharp, leading to the improvement of the response.
参考文献
| [1] | 张成芬.室内甲醛污染的危害及测定方法的研究[J].化学教学,2007(01):8-10. |
| [2] | Mccue JT;Ying JY.SnO2-In2O3 nanocomposites as semiconductor gas sensors for CO and NOx detection[J].Chemistry of Materials: A Publication of the American Chemistry Society,20075(5):1009-1015. |
| [3] | Lili Wang;Zheng Lou;Rui Wang.Ring-like PdO-MO with lamellar structure for gas sensor application[J].Journal of Materials Chemistry: An Interdisciplinary Journal dealing with Synthesis, Structures, Properties and Applications of Materials, Particulary Those Associated with Advanced Technology,201225(25):12453-12456. |
| [4] | Song XF;Wang ZJ;Liu YB;Wang C;Li LJ.A highly sensitive ethanol sensor based on mesoporous ZnO-SnO2 nanofibers[J].Nanotechnology,20097(7):75501-1-75501-5-0. |
| [5] | Devi GS.;Rao VJ.;Manorama S..GAS SENSITIVITY OF SNO2/CUO HETEROCONTACTS[J].Journal of the Electrochemical Society,19958(8):2754-2757. |
| [6] | Lee, Jae-Hyoung;Katoch, Akash;Choi, Sun-Woo;Kim, Jae-Hun;Kim, Hyoun Woo;Kim, Sang Sub.Extraordinary Improvement of Gas-Sensing Performances in SnO2 Nanofibers Due to Creation of Local p-n Heterojunctions by Loading Reduced Graphene Oxide Nanosheets[J].ACS applied materials & interfaces,20155(5):3101-3109. |
| [7] | Tamaki J.;Yamada Y.;Yamamoto Y.;Miura N.;Yamazoe N.;Shimanoe K..Dilute hydrogen sulfide sensing properties of CuO-SnO2 thin film prepared by low-pressure evaporation method[J].Sensors and Actuators, B. Chemical,19981/2(1/2):121-125. |
| [8] | Gun-Joo Sun;Sun-Woo Choi;Akash Katoch.Bi-functional mechanism of H2S detection using CuO-SnO2 nanowiresf[J].Journal of Materials Chemistry, C. materials for optical and electronic devices,201335(35):5454-5462. |
| [9] | Hu Y.;Zhou XH.;Han Q.;Cao QX.;Huang YX..Sensing properties of CuO-ZnO heterojunction gas sensors[J].Materials Science & Engineering, B. Solid-State Materials for Advanced Technology,20031/3(1/3):41-43. |
| [10] | Wang, X.;Wang, W.;Li, H.;Fu, C.;Ke, Y.;He, S..Development of a SnO _2/CuO-coated surface acoustic wave-based H _2S sensor with switch-like response and recovery[J].Sensors and Actuators, B. Chemical,20121(1):10-16. |
| [11] | Choi, S.-W.;Katoch, A.;Zhang, J.;Kim, S.S..Electrospun nanofibers of CuO-SnO_2 nanocomposite as semiconductor gas sensors for H_2S detection[J].Sensors and Actuators, B. Chemical,2013:585-591. |
| [12] | Wang, L.;Kang, Y.;Wang, Y.;Zhu, B.;Zhang, S.;Huang, W.;Wang, S..CuO nanoparticle decorated ZnO nanorod sensor for low-temperature H _2S detection[J].Materials science & engineering, C. Biomimetic and supramolecular systems,20127(7):2079-2085. |
| [13] | 陈伟根;李倩竹;徐苓娜;彭尚怡;刘军.CuO-SnO2纳米传感器的H2检测特性研究[J].仪器仪表学报,2013(10):2244-2250. |
| [14] | Ding, X.;Zeng, D.;Xie, C..Controlled growth of SnO_2 nanorods clusters via Zn doping and its influence on gas-sensing properties[J].Sensors and Actuators, B. Chemical,20102(2):336-344. |
| [15] | 何琴;黄保军;李颖颖;法文君.生物模板法制备微纳米二氧化锡[J].化工新型材料,2012(5):151-153. |
| [16] | Zhang Y;He XL;Li JP;Miao ZJ;Huang F.Fabrication and ethanol-sensing properties of micro gas sensor based on electrospun SnO2 nanofibers[J].Sensors and Actuators, B. Chemical,20081(1):67-73. |
| [17] | 贾锐军;彭同江;孙红娟;刘海峰.SnO2纳米薄膜的溶胶-凝胶法制备及气敏性能[J].化工新型材料,2008(1):15-16,30. |
| [18] | Hyo-Joong Kim;Jong-Heun Lee.Highly sensitive and selective gas sensors using p-type oxide semiconductors: Overview[J].Sensors and Actuators, B. Chemical,2014:607-627. |
| [19] | 唐伟;王兢.金属氧化物异质结气体传感器气敏增强机理[J].物理化学学报,2016(5):1087-1104. |
- 下载量()
- 访问量()
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%