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本論文永久網址:

研究生:

朱彥霖

研究生(外文):

CHU, YEN-LIN

論文名稱:

銀摻雜氧化鋅奈米片之氣體感測元件研究

論文名稱(外文):

Study for the Gas Sensors Based on Ag-doped ZnO Nanosheets

指導教授:

姬梁文

指導教授(外文):

JI, LIANG-WEN

口試委員:

蕭育仁、姬梁文、楊素華、林建德

口試委員(外文):

HSIAO, YU-JEN、JI, LIANG-WEN、YANG, SU-HUA、LIN, JIAN-DE

口試日期:

2018-06-30

學位類別:

碩士

校院名稱:

國立虎尾科技大學

系所名稱:

光電工程系光電與材料科技碩士班

學門:

工程學門

學類:

電資工程學類

論文種類:

學術論文

論文出版年:

2018

畢業學年度:

106

語文別:

中文

論文頁數:

118

中文關鍵詞:

氧化鋅、奈米片、水熱法、硝酸銀、氣體感測器、一氧化氮氣體

外文關鍵詞:

zinc oxide、nanosheets、hydrothermal method、silver nitrate、gas sensors、NO gas

相關次數:

被引用:0
點閱:340
評分:
下載:12
書目收藏:0

[1] Lin-Tzu Lai, Sheng-Joue Young, Yi-Hsing Liu, Zheng-Dong Lin and Shoou-Jinn
Chang, IEEE Transactions on Nanotechnology, vol. 14, pp. 776-781, (2015).
[2] Yi-Hsing Liu, Sheng-Joue Young, Member, IEEE, Liang-Wen Ji, and Shoou-Jinn
Chang, IEEE Transactions on Electron Devices, vol. 62, pp. 1-4, (2015).
[3] Yudong Zhu,Yingying Wang, Guotao Duan, Hongwen Zhang, Yue Li, Guangqiang
Liu, Lei Xu, Weiping Cai, Sensors and Actuators B, vol. 221, pp. 350-356,
(2015).
[4] 蔡嬪嬪、曾明漢, " 氣體感測器之簡介應用及市場 ", 第68期, pp. 50-56, (1992).
[5] Ahmed A. Ibrahim, G.N. Dar, Shabi Abbas Zaidi, Ahmad Umar, M. Abaker, H.
Bouzid, S. Baskoutas, Talanta., vol. 93, pp. 257-263, (2012).
[6] Chen Xian-Mei, Ji Yong, Gao Xiao-Yong, Zhao Xian-Wei, Chin. Phys. B, vol.
21, pp. 116801-1 ~ 116801-5, (2012).
[7] Jiabao Cui, Dejun Wang, Tengfeng Xie, Yanhong Lin, Sensors and Actuators
B, vol. 186, pp. 165-171, (2013).
[8] Sara Khosravi-Gandomani, Ramin Youseﬁ, Farid Jamali-Sheini, Nay Ming
Huang, Ceramics International, vol. 40, pp. 7957-7963, (2014).
[9] Oleg Lupan, Vasilii Cretu, Vasile Postica, Mahdi Ahmadi, Beatriz Roldan
Cuenya, Lee Chow, Ion Tiginyanu, Bruno Viana, Thierry Pauporte, Rainer
Adelung, Sensors and Actuators B, vol. 223, pp. 893-903, (2016).
[10] H. Chen, S.Y. Ma, H.Y. Jiao, G.J. Yang, X.L. Xu, T.T. Wang, X.H. Jiang,
Z.Y. Zhang, Journal of Alloys and Compounds, vol. 687, pp. 342-351,
(2016).
[11] Yas Al-Hadeethi, Ahmad Umar, Ahmed A. Ibrahim, Saleh H. Al-Heniti, Rajesh
Kumar, S. Baskoutas, Bahaaudin M. Raﬀah, Ceramics International, vol. 43,
pp. 6765-6770, (2017).
[12] 馬遠榮, " 低維奈米材料(科學發展) ", 東華大學應用物理研究所暨物理學系, 第382 期,
pp. 72-75, (2004).
[13] C. Weisbuch, H. Benisty and R. Houdre, J.Lumin., vol. 85, pp. 271-293,
(2000).
[14] Y. Cui, Semiconductor Nanowires for Nanotechnology: Synthesis,Properties,
Nanoelectronics, Nanophotonics, and Nanosensors, Ph.D.dissertation, Dept.
of Chem, Chem. Bio, Harvard University, (2002).
[15] Pearsons Handbook of Crystallographic Data, 4795, (1985).
[16] U. Ozgur, Ya. I. Alivov, C. Liu, A. Teke, M. A. Reshchikov, S. Dogan, V.
Avrutin, S.J. Cho, and H. Morkoc, J. Appl. Phys., vol. 98, pp. 1-103,
(2005).
[17] 周卓明, 壓電力學, 全華科技圖書, pp. 1-328, (2003).
[18] 林文男, " 基於有機/無稽混成半導體的新穎光感測器與光伏元件之研究 ", 國立虎尾科技
大學光電與材料科學研究所碩士論文, (2013).
[19] D. R. Vij, N. Singh," Luminescence and Related Properties of II-VI
Semiconductors ", Nova Science Publishers, pp. 1-389, (1998).
[20] X. T. Zhang, Y. C. Liu, Z. Z. Zhi, J. Y. Zhang, Y. M. Lu, D. Z. Shen, and
X. G. Kong, Lumine., vol. 99, pp. 149, (2002).
[21] K. Vanheusden, W. L. Warren, C. H. Seager, D. R. Tallant, J. A. Voigt and
B. E. Gnade, Appl. Phys. Lett., vol. 79, pp. 7983, (1996).
[22] B. Lin, Zhuxi Fu and Yunbo Jia, Appl. Phys. Lett., vol. 79, pp. 943,
(2001).
[23] J. Chen, Z. Feng, P. Ying, M. Li, B. Han, and C.Li, Physical chemistry
physics, vol. 6, pp. 4473, (2004).
[24] 鍾朝安, 銀導體連線技術, 奈米通訊, 卷20, No.1, (2013).
[25] C. L. Carnes, K. J. Klabunde, Langmuir, vol. 16, pp. 3764-3772, (2000).
[26] D. Jezequel, J. Guenot, N . Jouini, F. Fievet , Journal of Materials
Research, vol. 10, pp. 77-83, (1955).
[27] O. Milosevic, D. Uskokovic, L. J. Karanovic, M. Tomasevic-Canovic, M.
Trontelj, Journal of Materials Science, vol. 28, pp. 5211-5217, (1993).
[28] Y. Lin, Z. Tang, Z. Zhang, F.Yuan, Y. Ling, J. Lee, S. Huang, Journal of
the American Ceramic Society., vol. 83, pp. 2869-2871, (2000).
[29] T. Q. Liu, S. Osamu, M. Nobuyasu, K. Masanori, Journal of Materials
Science., vol. 21, pp. 3698, (1986).
[30] Q. Zhong, E. Matijevic, Journal of Materials Chemistry., vol. 6, pp. 443-
447, (1996).
[31] B. P. Lim, J. Wang, S. C. Ng, C. H. Chew, L. M. Gan, Ceramics
International., vol. 24, pp. 205-209, (1998).
[32] M. Singhal, V. Chhabra, D. O. Shah, Materials Research Bulletin, vol. 32,
pp. 239-247, (1997).
[33] J.D Meindl, Q. Chen, and J.A Davis, Science., vol. 293, pp. 2044, (2001).
[34] S.R. Hejazi, H.R. Madaah Hosseini, M. Sasani Ghamsari, Journal of Alloys
and Compounds, vol. 455, pp. 353-357, (2008).
[35] A.Umar, S.H. Kim, Y.S. Lee, K.S. Nahm, Y.B. Hahn, Journal of Crystal
Growth, vol. 282, pp. 131-136, (2005).
[36] Timothy J. Trentler, Kathleen M. Hickman, Subhash C. Goel, Ann M. Viano,
Patrick C. Gibbons, William E. Buhro, Science, vol. 270, pp. 1791-1794,
(1995).
[37] Kwang Sik Kim, Hyoun Woo Kim, Physica B, vol. 328, pp. 368-371, (2003).
[38] Sriram Muthukumar, Haifeng Sheng, Jian Zhong, Student Member, IEEE, Zheng
Zhang, Nuri William Emanetoglu, Associate Member, IEEE, and Yicheng Lu,
vol. 2, pp. 50-54, (2003).
[39] M. Yan, H. T. Zhang, E. J. Widjaja, and R. P. H. Chang, Journal of
Applied Physics, vol. 94, pp. 5240-5246, (2003).
[40] S. S. Brenner and G. W. Sears, Acta Metallurgica, vol. 4, pp. 268,
(1956).
[41] A. P. Li, F. Muller, A. Birner, K. Nielsch, and U. Gosele, J. Appl.
Phys., vol. 84, pp. 6023, (1998).
[42] H. J. Fan, W. Lee, R. Scholz, A. Dadgar, A. Krost, K. Nielsch, M.
Zacharias, Nanotechnology, vol. 16, pp. 913-917, (2005).
[43] Min Guo, ChuanYu Yang, Mei Zhang, YanJun Zhang, Teng Ma, XiDong Wang,
XinDong Wang, Electrochimica Acta, vol. 53 , pp. 4633-4641, (2008).
[44] Seung-Ho Jung, Eugene Oh, Kun-Hong Lee, Wanjun Park, and Soo-Hwan Jeong,
Advanced Materials, vol. 19, pp. 749-753, (2007).
[45] Hui Zhang, Deren Yang, Yujie Ji, Xiangyang Ma, Jin Xu, and Duanlin Que,
Journal of Physical Chemistry B, vol. 108, pp. 3955-3958, (2004).
[46] Lionel Vayssieres, Karin Keis, Anders Hagfeldt, and Sten-Eric Lindquist,
Chemistry of Materials, vol. 13, pp. 4395-4398, (2001).
[47] Youngjo Tak and Kijung Yong, Journal of Physical Chemistry B, vol. 109,
pp. 19263-19269, (2005).
[48] 劉芳佐, " 以水熱法製備之氧化鋅奈米桿之氣體感測特性 ", 國立台灣科技大學化學工程研
究所碩士論文, (2009).
[49] N.Yamazoe, J.Fuchigami, M.Kishikawa, and T.Seiyama, Surf. Sci., vol. 86,
pp. 335, (1979).
[50] Abu Z. Sadek, Student Member, Supab Choopun, Wojtek Wlodarski, Member,
Samuel J. Ippolito, and Kourosh Kalantar-zadeh, IEEE Sensors Journal,
vol. 7, pp. 919-924, (2007).
[51] 陳怡文, " 自我催化VLS機制成長ZnO奈米線及其應用於氣體感測器之分析 ", 國立臺北科
技大學材料科學與工程研究所碩士論文, (2006).
[52] P.P. Sahay, S. Tewari, S. Jha, M Shamsuddin, Materials Science, vol. 40,
pp. 4792, (2005).
[53] 高千婷, " 半導體奈米顆粒氧化鋅氣體感測器之設計與特性 ", 大同大學材料工程研究所碩
士論文, (2000).
[54] 許智翔, " 藉由奈米金屬粒子結合二氧化錫薄膜增強氣體感測 ", 國立雲林科技大學電子工
程系微電子與光電工程研究所碩士論文, (2017).
[55] 黃光緯, " 水熱法成長鋁摻雜氧化鋅奈米材料與其光電元件之專題製作 ", 國立雲林科技大
學電子工程系, (2012).
[56] Cheng-Liang Hsu, Hsieh-Heng Li, and Ting-Jen Hsueh, ACS Appl, vol. 5, pp.
11142-11151, (2013).

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