研究生: |
陳柏霖 Chen, Po-Lin |
---|---|
論文名稱: |
利用陽極氧化鋁模板製備奈米級二氧化鈦有害氣體感測元件之研究 The Study of Fabrication of Nano Titanium Dioxide Harmful Gas Sensor by Template of Anodic Aluminum Oxide |
指導教授: |
郭金國
Kuo, Chin-Guo |
學位類別: |
碩士 Master |
系所名稱: |
工業教育學系 Department of Industrial Education |
論文出版年: | 2021 |
畢業學年度: | 109 |
語文別: | 中文 |
論文頁數: | 82 |
中文關鍵詞: | 陽極氧化鋁 、二氧化鈦 、氣體感測元件 、甲醛 、一氧化碳 |
英文關鍵詞: | AAO, TiO2, Gas sensor, Formaldehyde, Carbon monoxide |
DOI URL: | http://doi.org/10.6345/NTNU202100219 |
論文種類: | 學術論文 |
相關次數: | 點閱:251 下載:0 |
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本研究旨在製備出奈米級二氧化鈦氣體感測元件來感測有害氣體,在陽極氧化鋁(Anodic Aluminum Oxide, AAO)模板濺鍍白金(platinum, Pt)作為導電極,再以蒸鍍鋁(Aluminum, Al)作為薄膜支撐的底座,經由濕式蝕刻的方法去除AAO的阻障層以及擴孔處理,最終以原子層沉積法將二氧化鈦(Titanium Dioxide, TiO2)沉積於製備好的模板中形成奈米結構。製作的過程中探討不同製程參數所形成的二氧化鈦奈米結構的表面形貌與晶體結構,其性質以掃瞄式電子顯微鏡(Scanning Electron Microscopy, SEM)、能量色散X射線光譜(Energy-dispersive X-ray Spectroscopy, EDS)檢測。製作完成之奈米級有害氣體感測元件,以氣體感測設備來量測甲醛(Formaldehyde, CH2O)、一氧化碳(Carbon monoxide, CO)氣體之反應靈敏度,實驗結果顯示奈米級二氧化鈦有害氣體感測元件,以溫度和氣體濃度的實驗參數搭配。在室溫(25˚C)下感測CH2O靈敏度最高為37.1%;感測CO靈敏度最高為24.0%。然而在加熱的狀態下,感測CH2O在0.5 ppm、500˚C時其靈敏度最高為63.2%;感測CO在600 ppm、500˚C時其靈敏度最高為90.2%。
In this study, a metal oxide semiconductor gas sensor was fabricated to detect harmful gases. A metal oxide semiconductor was a nano titanium dioxide (TiO2) produced by atomic layer deposition (ALD) in anodic aluminum oxide (AAO) template. An anodic aluminum oxide was suitable for producing nanotube or nanowire process. It had high porosity, good regularity and good array. In producing process of sensor, sputter platinum (Pt) on the AAO as layer of conductive, then thermal vapor aluminum (Al) as the base to support the film. The barrier layer of AAO is removed by wet etching and the hole expansion is processed. Finally, TiO2 was deposited on the prepared template by atomic layer deposition to form a nano structure. Using this sensor to detect formaldehyde (CH2O) and carbon monoxide (CO) at the different concentration and temperature. The experimental results show that the highest sensitivity for detecting CH2O and CO at the room temperature (25˚C) were respectively 37.1% and 24.0%. The highest sensitivity for detecting CH2O and CO at the heat situation were respectively 63.2%, 0.5 ppm at 500˚C and 90.2%, 600 ppm at 500˚C.
[1] World Health Organization, “ WHO reveals leading causes of death and disability worldwide: 2000-2019, December 9, 2020. Retrieved from https://www.who.int/news/item/09-12-2020-who-reveals-leading-causes-of-death-and-disability-worldwide-2000-2019
[2] World Health Organization,“ The top 10 causes of death”, May 24, 2018. Retrieved from https://www.who.int/news-room/the-top-10-causes-of-death
[3] World Health Organization,“ 7 million premature deaths annually linked to air pollution“, Public Health, Environmental and Social Determinants of Health , Issue 63, March 25, 2015.
[4] World Health Organization,“ WHO’s First Global Conference on Air Pollution and Health” , Switzerland Geneva, November 1, 2018.
[5] Matteo Carpentieri, Prashant Kumar, Alan Robins, “An overview of experimental results and dispersion modelling of nanoparticles in the wake of moving vehicles”, Environmental Pollution, vol.159(3), pp. 685-693, 2011.
[6] 國家衛生研究院,“2020國民健康白皮書”,衛生福利部,pp.26-31,2018
[7] Mahmoud Mohammadyan ,Ahmad Alizadeh-Larimi, Siavash Etemadinejad et al,“Particulate Air Pollution at Schools: Indoor-Outdoor Relationship and Determinants of Indoor Concentrations”, Aerosol and Air Quality Research, vol.17(3), pp. 857-864, 2017.
[8] 行政院環境保護署,“「室內空氣品質」的重要性”,2020
[9] Sumedha M. Joshi Tejonidhi’, “The sick building syndrome”, Indian J Occup Environ Med , vol.12(2), pp. 61–64, 2008.
[10] 彭定吉,“集合住宅室內空氣環境境(CO2、CO、粉塵)現場量測方法之探討”,國立成功大學建築工程研究所,碩士,2003。
[11] Zohir Chowdhury,etc., “Quantification of Indoor Air Pollution from Using Cookstoves and Estimation of Its Health Effects on Adult Women in Northwest Bangladesh”, Aerosol and Air Quality Research, vol.12(4), pp463-475, 2012.
[12] Prashant Kumar, “Real-time sensors for indoor air monitoring and challenges ahead in deploying them to urban buildings”, Science of The Total Environment, vol 560-561(1), pp150-159, 2016.
[13] 行政院環境保護署,室內空氣品質檢驗方法,2020。
[14] Ji-Peng Lin, Jun-Hua Liu, “Recognizing Frequency Characteristics of Gas Sensor Array”, Academic Journal of Xi'an Jiaotong University , vol 19(2) , pp126-130, 2007.
[15] Ahmad I. Ayesh, “Metal/Metal-Oxide Nanoclusters for Gas Sensor Applications”, Journal of Nanomaterials ,vol 2016, pp656-672, 2016.
[16] Rahul Kumar .atc, “Room-Temperature Gas Sensors Under Photoactivation: From Metal Oxides to 2D Materials”, Nano-Micro Letters, vol 2020(11), pp292-328, 2020.
[17] 彭軍、彭森,“有害氣體監測系統設計”, 邵陽學院信息工程學院,環球市場期刊,2018年06期,第385-390頁,2018。
[18] 孫國書,“室內空氣品質管理與改善簡介”,經濟部工業局,2017年。
[19] 行政院環境保護署,“室內空氣品質標準”,2021。
[20] 涂玉峰,“室內空氣環境綜合評估指標之探討-以台灣南部工業區辦公大樓為例”,國立成功大學建築工程研究所,碩士,2010。
[21] 許逸群,“室內空氣品質管理法&健康危害及改善”,永續環境暨先進遙測研究中心,第3-17頁,2017年。
[22] Illinois Department of Public Health ,“How can Formaldehyde affect my health?”, July 16, 2018 , Retrieved from https://www.dph.illinois.gov/topics-
services/environmental-health-protection/toxicology/indoor-air-quality-healthy-homes/formaldehyde.
[23] Ravindra V. Gadhave, Prakash A. Mahanwar and Pradeep T. Gadekar, “Factor Affecting Gel Time/Process-Ability of Urea Formaldehyde Resin Based Wood Adhesives”, Open Journal of Polymer Chemistry ,vol.7(2), pp.33-42, 2017.
[24] 台北市政府環境保護局,“「室內空氣品質管理法」所指之室內空氣污染物有哪些?目前標準為何?”,2016。
[25] National Organization for Rare Disorders,“Formaldehyde Poisoning- Signs & Symptoms”March 22, 2017, Retrieved from https://rarediseases.org/rare-disea
ses/formaldehyde-poisoning/.
[26] Mary ,“甲醛對身體的危害”,健談-環境賀爾蒙 甲醛篇, 2014。
[27] 行政院環境保護署,“空氣中氣態之醛類化合物檢驗方法-以DNPH衍生化之高效能液相層析測定法”,2017。
[28] Xuan Zhang, Xiaosheng Shen, Yuan Wang, Youqiong Cai, Dongmei Huang*,“The Research Progress of Detection Method of Formaldehyde in Food”, Advances in Engineering Research , vol 135, 2017.
[29] Hua-ping Yang,“Research Progress of Indoor Formaldehyde Detection Method and Preventive Measures”, Chemical Design Newsletter, vol 10, pp.124, 2017.
[30] 徐理明,差分光學吸收在線測量有害氣體研究,電子科技大學,碩士,2010。
[31] 程望斌,光譜法測定空氣中甲醛濃度的方法研究,華中科技大學,碩士,2006。
[32] 林佳欣,“電化學式鄰苯二甲醛消毒劑檢測系統之開發”,國立臺灣大學生物產業機電工程學研究所,碩士,2016。
[33] 柏林洋,微量甲醛分析方法的研究,南京工業大學,碩士,2005。
[34] 曾佩如、朱珮芸、傅 強、陳怡妃、賴宜弘、蔡志賢、洪珮瑜,“降低移動污染源管理措施蒐集與彙析”,交通部運輸研究所,2018。
[35] 行政院環境保護署,“移動污染源排放總量推估及管制專案工作計畫”,2017。
[36] 行政院環境保護署,“空氣污染排放總量資料庫清冊系統9.0(Taiwan Emission Data System, TEDS)”,2019。
[37] Maurizio Manigrasso, Claudio Natale, Matteo Vitali, Carmela Protano and Pasquale Avino, “Pedestrians in Traffic Environments: Ultrafine Particle Respiratory Doses.”,Environmental Research and Public Health, vol 14 , pp. 288, (2017).
[38] 科技部自然科學及永續研究發展司,“都市空氣污染暴險人口分佈”,2015。
[39] 謝忠岳、黃立言、蔡宗能、李柏群*,“一氧化碳中毒對心臟功能的影響”內科學誌,27期5卷,第223-232頁,2016。
[40] 行政院環境保護署,“空氣中一氧化碳自動檢測方法- 紅外光法”,2016。
[41] Shu-Hua Chien, Jiunn-Min Hwang, Yu-Chin Chang, “Support Effect on Nickel Catalysts: An Infrared Study of CO Adsorption”, Bulletin of the Institute of Chemistry Academia Sinica, vol 42, pp.75-85, 1989.
[42] 劉國晏,“高真空壓鑄法製備陣列式錫鉛合金奈米線氣體感測器”,國立臺北科技大學機電整合研究所,碩士,2012。
[43] N. Yamazoe, J. Fuchigami, M. Kishikawa, and T. Seiyama, “Interactions of tin oxide surface with O2, H2O and H2,” Surface Science, vol. 86, pp. 335-344, 1979.
[44] 楊力儼、柯廷勳、曾文甲,“固態氣體感測器介紹”,科儀新知-智慧氣體感測器篇,第218期,2019。
[45] 趙苡捷,“使用P3HT製作有機氣體感測器檢測呼氣氨濃度”,國立臺灣師範大學工業教育研究所,碩士,2015。
[46] H. Nanto, T. Minami, and S. Takata, “Zinc‐oxide thin‐film ammonia gas sensors with high sensitivity and excellent selectivity,” Journal of Applied Physics, vol. 60, pp. 482-484, 1986.
[47] 李奕賢,“非發散式紅外線器體感測器之設計與應用”,國立臺灣大學電子工程學研究所,碩士,2018。
[48] M. Niggemann, A. Katerkamp, M. Pellmann, P. Bolsmann, J. Reinbold, and K. Cammann, “Remote sensing of tetrachloroethene with a micro-fibre optical gas sensor based on surface plasmon resonance spectroscopy,” Sensors and Actuators B: Chemical, vol. 34, pp. 328-333, 1996.
[49] 謝汶軒,“次微米級拉細光纖氣體感測器穩定性及靈敏度提升之研究”,逢甲大學光電研究所,碩士,2016。
[50] E.-B. Lee, I.-S. Hwang, J.-H. Cha, H.-J. Lee, W.-B. Lee, J. J. Pak, et al., “Micromachined catalytic combustible hydrogen gas sensor,” Sensors and Actuators B: Chemical, vol. 153, pp. 392-397, 2011.
[51] 劉承軒,“二氧化鈦聚合奈米球應用在甲醛氣體感測器之研究”,靜宜大學應用化學研究所,碩士,2016。
[52] Fu-jian Ren ,atc, “Performance of Pt-TiO2 Electrocatalyst for CO Oxidation in the Electrochemical Gas Sensor”, Changchun Institute of Applied Chemistry, vol 5, pp.472-473, 2002.
[53] Zhang Jiaqi ,“Research for Detection of Ammonia Gas Through QCM Gas Sensor Modified by Nanometer TiO2”, Instrument Technology and Sensor, vol 2, pp.5-7, 2015.
[54] Shun Tan, atc,“ Nanohybrid TiO2/carbon black sensor for NO2 gas”, Department of Materials Engineering, vol 3, pp.225-229, 2007.
[55] 李哲名,“以射頻磁控濺鍍法製備TiO2/SnO2複合薄膜之臭氧氣體感測器”, 靜宜大學應用化學研究所,碩士,2010。
[56] Chin-Guo Kuo,Jung-Hsuan Chen *,Yi-Chieh Chao ,Po-Lin Chen, “Fabrication of a P3HT-ZnO Nanowires Gas Sensor Detecting Ammonia Gas”,Sensors , vol 18(1), pp.37, 2018.
[57] Ding Pei ,“In Situ Growth of Intrinsic ZnO Nanowires for Trace-level H2S Gas Sensing”, Instrument Technology and Sensor, vol 11, pp.21-24, 2017.
[58] 陳律廷,“具粗糙化結構晶種層之黑金/氧化鋅奈米柱異質接面NO2氣體感測器之研究”,國立成功大學光電科學與工程研究所,碩士班,2019。
[59] 吳宗霈,“氧化鋅奈米線複合聚苯胺之一氧化碳氣體感測器”,國立臺南大學綠色能源科技學系碩士班,碩士,2019。
[60] 蕭家斌,“氧化鋅奈米樹狀結構應用於乙醇氣體感測器之研究”,國立中山大學電機工程學系研究所,碩士,2014。
[61] 陳信宏,“具有極高靈敏度之單根氧化鋅奈米線一氧化氮氣體感測器”,國立清華大學材料科學工程學系研究所,碩士,2012。
[62] Zeng Wen ,“Nano SnO2 Based Gas Sensor for Formaldehyde Gas Detection”, Nano Technology and Precision Engineering,vol 5 ,pp.387-391, 2009.
[63] Pengjian Wang, Tingbiao Yuan, atc , “PdO/SnO2 heterostructure for low-temperature detection of CO with fast response and recovery.”, RSC Advances ,vol 40 ,pp.124-128,2019.
[64] Ling-Min Yu,Chang-Chun Zhu,atc ,“Gas-Sensing Characteristics of SnO2 Nanoparticles to CH4”, Journal of Xi'an Jiaotong University, vol 43(6), pp.118-122, 2009.
[65] Yang Bing ,“Preparation of Mesoporous SnO2 Nanomaterials and Study on Its Gas Sensing Properties of Alcohol”, Journal of Xi'an Jiaotong University, vol 8, pp.670-675, 2016.
[66] Cao Junrui,“Acetone gas sensor based on CeO2-doped ZnO with high sensitivity at low temperature” , Electronic components and materials, vol 9, pp.45-53, 2020.
[67] 陳孝修,“兩階段水熱法合成 p-CeO2/n-ZnO 異質接面奈米複合材料及其二氧化氮氣體感測特性”,中興大學材料科學與工程學系研究所,碩士,2014。
[68] Li Sufang ,atc,“The influence of carbon monoxide gas on the ZrO2 sensor”, Journal of Hunan University of Science and Technology, vol 2, pp.92-94, 2003.
[69] Chinese Xiao ,“Fabrication of PdO Nanoparticles for Formaldehyde Gas Sensing at Room Temperature”, Sensor technology, vol 5, pp.642-646, 2016.
[70] Yu-Ju Chiang, “ CO Sensing by Reactive-sputter-deposited PdO Nanoflakes at Atmospheric Pressure”, Vacuum Technology, vol 25(4), pp.40-45, 2012.
[71] Da-Wei Wang,“Study of a Low Concentration NO2 Gas Sensor Based WO3 Nanometer Material”, Computational measurement technology, vol 26, pp.50-53, 2006.
[72] H. Masuda and K. Fukuda, “Ordered metal nanohole arrays made by a two-step replication of honeycomb structures of anodic alumina,” Science, vol. 268, pp. 1466-1468, 1995.
[73] H. Chik and J. Xu, “Nanometric superlattices: non-lithographic fabrication, materials, and prospects,” Materials Science and Engineering: R: Reports, vol. 43, pp. 103-138, 2004.
[74] G. Thompson, “Porous anodic alumina: fabrication, characterization and applications,” Thin solid films, vol. 297, pp. 192-201, 1997.
[75] O. Jessensky, F. Müller, and U. Gösele, “Self-organized formation of hexagonal pore arrays in anodic alumina,” Applied Physics Letters, vol. 72, pp. 1173-1175, 1998.
[76] T. Ohgai, X. Hoffer, L. Gravier, J.-E. Wegrowe, and J.-P. Ansermet, “Bridging the gap between template synthesis and microelectronics: spin-valves and multilayers in self-organized anodized aluminium nanopores,” Nanotechnology, vol. 14, pp. 978, 2003.
[77] J. Homola, S. S. Yee, and G. Gauglitz, “Surface plasmon resonance sensors: review,” Sensors and Actuators B: Chemical, vol. 54, pp. 3-15, 1999.
[78] A. Li, F. Müller, A. Birner, K. Nielsch, and U. Gösele, “Hexagonal pore arrays with a 50–420 nm interpore distance formed by self-organization in anodic alumina,” Journal of applied physics, vol. 84, pp. 6023-6026, 1998.
[79] Sun Xiaotong, Chen Nan, Liang Hanxue, Li Zengling, Liu Qianwen, Qu Liangti, “Progress of Fabrication of One-Dimensional Hybrid Nanomaterials by Template-Confined Growth and Their Diverse Applications”, Angewandte Chemie ,vol 2 ,pp.123-133 ,2020.
[80] Liang Ling-ling, Zhao Yan, Feng Chao, “Fabrication and ultraviolet visible near infrared absorption properties of silver nano arrays based on aluminum”, Journal of Physics ,vol 6 , pp.207-215, 2020.
[81] 謝宜澍,利用鎳金合金奈米柱製備之葡萄糖感測器完成非酶葡萄糖感測,國立成功大學微電子工程研究所,碩士,2019。
[82] 郭柏均,以陽極氧化鋁及奈米球微影製程作仿生黏著結構,國立臺灣大學機械工程學研究所,碩士,2017。
[83] Chin-Guo Kuo, Jeng-Ji Huang, Jung-Hsuan Chen, Ren-Jun Zeng,“Fabrication of High Array Zinc–Indium Oxide Nanowires and a Nanowire Gas Sensor ”, Sensors and Materials, vol 29(4), pp.533-538, 2017.
[84] 陳旻傳,“以陽極氧化鋁模板輔助成長高表面積鎳奈米柱”,國立虎尾科技大學光電工程系光電與材料科技碩士班,碩士,2017。
[85] Chin-Guo Kuo , Ho Chang , Jian-HaoWang, “Fabrication of ZnO Nanowires Arrays by Anodizationand High-Vacuum Die Casting Technique, and Their Piezoelectric Properties”,Sensors ,vol 16 (4) ,pp.431 ,2016.
[86] Chin-Guo Kuo, Ho Chang, Kevin Chih-Cheng Lu, Guo-yan Liu, “ Fabrication and Characterization of a Pb-Sn Nanowire Array for Detecting Carbon Monoxide”,Journal of Nanoscience and Nanotechnology , vol 16 (2) ,pp.1834-1838 ,2016
[87] Wei-Fan Hsu; Chin-Guo Kuo; Yi-Chieh Chao; Feng-Renn Juang; Cheng-Fu Yang; Jeen-Fong Lee, “Growth of ZnO Nano-Wire Arrays Using AAO Template and Atomic-Layer Deposition Method”, International Conference on Applied System Innovation (ICASI), Okinawa, Japan ,2016.
[88] Ho Chang, Jen-Ching Huang, Jeen-Fong Li, Chin-Guo Kuo,Yong- Chin You, “Prediction of Surface Morphology for Nanostructure Fabrication by Nano-oxidation technology”, Materials ,vol 8(12) ,pp.8437-8451 ,2015.
[89] Yuan-Yuan Guo, Ming Wang, Xiao-Bo Mao, Yue-Xiu Jiang, Chen Wang, Yan-Lian Yang, “Growth Mechanism for Controlled Synthesis of Metal Nanotube and Nanowire Arrays Using Anodic Aluminum Oxide Templates”, Physical Chemistry ,vol 26(7) ,pp.2037-2043, 2010.
[90] 李世宏,“利用陽極氧化鋁模板在矽基材上成長TixWyO的奈米結構材料”,國立交通大學工學院碩士在職專班半導體材料與製程設備組,碩士,2010
[91] Yan-Fei Hu,“Phase Transition and Thermodynamic Properties of TiO2”, Physical Chemistry, vol 26(6), pp.1664-1668, 2010.
[92] Weichao Wang,“Effect of defects in TiO2 nanoplates with exposed{001}facets on the gas sensing properties”, Chinese Chemical Letters, vol 6, pp.1261-1265, 2019.
[93] Xiong-Ying Liu,Guang-Zhou Huang,“Atomic Layer Deposition and Its Applications in Semiconductor”, vacuum, vol 43(4) , pp.1-6, 2006.
[94] Li Shuan-Kui,“Improving the Performance of Thermoelectric Materials by Atomic Layer Deposition-based Grain Boundary Engineering” Structural Chemistry, vol 5, pp.831-837, 2020.