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采用沉淀法制备了纳米氧化锌粒子,着重对其进行了不同条件(电场强度、极化温度)下的外电场极化处理.以X射线衍射仪和拉曼光谱仪对产物的结构、拉曼位移等进行了表征.测试了氧化锌极化产物在乙醇、丙酮气体中的气敏性能,研究了外电场效应对纳米氧化锌拉曼光谱和气敏性能的影响机制.结果表明,纳米氧化锌样品在外电场中存在着极化电场强度和温度的阈值,当电场强度和温度分别大于9375 V·cm-1和150 ℃时,纳米氧化锌试片出现明显的漏电现象,极化效应显著降低并消失.在电场强度和温度阈值范围内,外电场极化作用能够导致氧化锌437 cm-1处的拉曼特征峰强度明显降低.随外电场强度和极化温度增加,纳米氧化锌元件在丙酮气体中的灵敏度逐渐升高,在乙醇气体中的灵敏度逐渐降低,即外电场极化可以有效调控纳米氧化锌的气敏选择性.Control and administration of various dangerous gases existing in the environment is very important both for safety in the workplace and for quality of daily life, such as acetone and ethanol, etc. Zinc oxide, a well-known n-type semiconductor with a direct wide band-gap of 3.37 eV, is a very promising gas sensing material. However, zinc oxide's limited selectivity, relatively long response/recovery time, high-power consumption, and lack of long-term stability have restricted its applications in high-standard gas detection. Therefore, increasing gas sensing selectivity is a crucial issue for ZnO application in the gas sensing field. So far, many researches have reported and discussed the effects of morphologies, structures, doping of gas sensing materials, on its sensing performance. In this work, we intend to investigate and theoretically analyze how the polarization of the external electric field affects gas sensing performance and selectivity. Zinc oxide nanoparticles, as a testing gas sensing material, are synthesized by simple precipitation method. Then they are pressed into a disc and polarized under an external electric field with different electric field intensities at different temperatures. The structure and Raman activity for each of the unpolarized ZnO and the polarized ZnO are characterized using X-ray diffraction and Raman spectrometry, respectively. The gas sensing performances of unpolarized and polarized ZnO based sensors to ethanol and acetone are carefully examined using a chemical gas sensing system. The mechanism of external electric field polarization effect on gas sensitivity is discussed. The results reveal that there exists a threshold value for each of voltage and temperature for ZnO polarization under an external electric field. When the voltage and temperature are over 9375 V·cm-1 and 150℃, respectively, the leakage of electricity in ZnO disk happens and the polarization effect gradually disappears. Within the above voltage and temperature limits, Raman peak intensity of the polarized ZnO at 437 cm-1 obviously decreases after external electric field polarization. The response of the polarized ZnO sensor to acetone increases with external electronic field and polarization temperature increasing, while the response to ethanol decreases, which indicates that external electric field polarization can effectively adjust the gas sensing selectivity of nano zinc oxide. Raman analysis indirectly shows that the enhanced gas sensing selectivity of ZnO by the polarization effect of the external electric field is due to oxygen vacancy and zinc vacancy directionally moving under the action of an external electric field. Thus it can be seen that the polarization of the external electric field acting on gas sensing material is a promising effective method to improve gas sensing selectivity.
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Keywords:
- external electric field /
- nano zinc oxide /
- Raman spectrum /
- gas sensing
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[1] Wang J X, Yang J, Han N, Zhou X Y, Gong S Y, Yang J F, Hu P, Chen Y F 2017 Mater. Design 121 69
[2] Pushpa N, Kokila M K 2017 J. Lumin. 190 100
[3] Park S H, Hong W P, Kim J J 2017 Solid State Commun. 261 21
[4] Xu J Q, Xue Z J, Qin N, Cheng Z X, Xiang Q 2017 Sensor Actuat. B: Chem. 242 148
[5] Calestani D, Villani M, Culiolo M, Delmonte D, Coppedé N, Zappettini A 2017 Sensor Actuat. B: Chem. 245 166
[6] Yang S, Liu Y L, Chen T, Jin W, Yang T Q, Cao M C, Liu S S, Zhou J, Zakharova G S, Chen W 2017 Appl. Surf. Sci. 393 377
[7] Chen R S, Wang J, Xia Y, Xiang L 2018 Sensor Actuat. B: Chem. 255 2538
[8] Wang H, Li H Y, Li S C, Liu L, Wang L Y, Guo X X 2017 J. Mater. Sci.: Mater. El. 28 958
[9] Pimpang P, Zoolfakar A S, Rani R A, Kadir R A, Wongratanaphisan D, Gardchareon A, Kalantar-zadeh K, Choopun S 2017 Ceram. Int. 43 S511
[10] Al-Hadeethi Y, Umar A, Al-Heniti S H, Kumar R, Kim S H, Zhang X X, Raffah B M 2017 Ceram. Int. 43 2418
[11] Khayatian A, Safa S, Azimirad R, Kashi M A, Akhtarianfar S F 2016 Physica E 84 71
[12] Lupan O, Postica V, Gröttrup J, Mishra A K, Leeuw N H, Adelung R 2017 Sensor Actuat. B: Chem. 245 448
[13] Uddin A S M I, Phan D T, Chung G S 2015 Sensor Actuat. B: Chem. 207 362
[14] Kim G, Bernholc J, Kwon Y K 2010 Appl. Phys. Lett. 97 063113
[15] Tang K, Qin R, Zhou J, Qu H, Zheng J X, Fei R X, Li H, Zheng Q Y, Gao Z X, Lu J 2011 J. Phys. Chem. C 115 9458
[16] Alfieri J, Kimoto T 2010 Appl. Phys. Lett. 97 043108
[17] An Y H, Xiong B T, Xing Y, Shen J X, Li P G, Zhu Z Y, Tang W H 2013 Acta Phys. Sin. 62 073103 (in Chinese) [安跃华, 熊必涛, 邢云, 申婧翔, 李培刚, 朱志艳, 唐为华 2013 62 073103]
[18] Wang Y Z, Wang B L, Zhang Q F, Zhao J J, Shi D N, Yunoki S J, Kong F J, Xu N 2012 J. Appl. Phys. 111 073704
[19] Zhang Q, Qi J J, Huang Y H, Li X, Zhang Y 2011 Appl. Phys. Lett. 99 063105
[20] Li S M, Zhang L X, Zhu M Y, Ji G J, Zhao L X, Yin J, Bie L J 2017 Sensor Actuat. B: Chem. 249 611
[21] Li Y, Liu M, L T, Wang Q, Zhou Y L, Lian X X, Liu H P 2015 Electron. Mater. Lett. 11 1085
[22] Hansen M, Truong J, Xie T, Hahm J 2017 Nanoscale 9 8470
[23] Jammula R K, Pittala S, Srinath S, Srikanth V V S S 2015 Phys. Chem. Chem. Phys. 17 17237
[24] Ni H Q, Lu Y F, Liu Z Y, Qiu H, Wang W J, Ren Z M, Chow S K, Jie Y X 2001 Appl. Phys. Lett. 79 812
[25] David R L 2005 CRC Handbook of Chemistry and Physics (Boca Raton: Copyright CRC Press LLC) pp9-47
[26] Gholami M, Khodadadi A, Firooz A, Mortazavi Y 2015 Sensor Actuat. B: Chem. 212 395
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