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研究生: 蔡顯仁
Hsien-Jen Tsai
論文名稱: 無機氣體表面聲波感測器研製與應用
Preparation and Application of Surface Acoustic Wave Sensor for Inorganic Gases
指導教授: 施正雄
Shih, Jeng-Shong
學位類別: 碩士
Master
系所名稱: 化學系
Department of Chemistry
論文出版年: 2005
畢業學年度: 93
語文別: 中文
論文頁數: 154
中文關鍵詞: 表面聲波感測器主成份分析倒傳遞類神經網路迴歸分析
英文關鍵詞: surface acoustic wave sensor, principal component analysis, back propagation network, regression analysis
論文種類: 學術論文
相關次數: 點閱:245下載:0
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    • 本研究中研製一多頻道氣體表面聲波感測器(surface acoustic wave sensor, SAW)以偵測空氣中二氧化氮(nitrogen dioxide, NO2)及一氧化碳(carbon monoxide, CO),在表面聲波晶片上塗佈Ru3+/ cryptand[2,2]與Zn2+/ cryptand[2,2]辨識膜分別對NO2及CO作感測,本研究發現待測氣體與塗佈物間吸附現象為物理吸附,可反覆使用具良好再現性,並且使用壽命超過一個月;由氣體濃度效應研究中發現,本研究研製的表面聲波感測器頻率訊號與CO及NO2濃度皆有良好的線性關係,其中Ru3+/ crypatnd[2,2]及Zn2+/ cryptand[2,2]偵測NO2及CO的偵測下限分別為0.176與0.699 ppm,皆低於恕限量及排放標準。本研究亦探討環境溫度和濕度對表面聲波感測器的影響,各種空氣中有機揮發污染物對表面聲波感測器偵測NO2與CO可能造成的干擾亦被探討。
    本研究亦藉由數學統計方法中的主成分分析法(principal component analysis, PCA)來確定本研究所選擇的塗佈物足以分辨NO2及CO,由研究結果顯示在二維的X-Y主成份分數散佈圖(PCA scores plot),其中NO2與CO各自成群且相互分離即可證明確實足以分辨NO2及CO。另外亦使用類神經網路中監督型倒傳遞神經網路(back propagation network, BPN)來作確認及辨別NO2和CO,倒傳遞神經網路系統亦顯示所選的表面聲波塗佈物Ru3+/ crypatnd[2,2]和Zn2+/ cryptand[2,2]確可分辨NO2及CO作為定性分析,多變項複迴歸分析技術(multivariate multiple regression analysis)亦用來作定量分析。

    A multichannel surface acoustic wave (SAW) gas sensor system was prepared to detect NO2 and CO in the air. The coated Ru3+/ cryptand[2,2] and Zn2+/ cryptand[2,2] SAW crystals were applied to recognize NO2 and CO, respectively. The physical adsorption was found for the adsorption of these inorganic gases onto respective coating materials. The SAW sensor also showed good reproducibility and good enough lifetime of ≧ 30 days for detection of NO2 and CO. The detection limits of this SAW sensor with Ru3+/ cryptand[2,2] and Zn2+/ cryptand[2,2] coatings for NO2 and CO were 0.172 and 0.699 ppm respectively, which were lower than occapational exposure limits for both gases and implied that the developed SAW sensor in this study could be employed for environmental analysis for both gases. The concentration effect of NO2 and CO on the frequency responses of the SAW sensor was studied and showed good linear responses with the concentrations of NO2 and CO, respectively. Effects of temperature and humidity on the SAW sensor were also investigated and discussed. Furthermore, the interference of some organic vapors to the detection of NO2 and CO with the SAW sensor was also studied and discussed.
    The principal component analysis (PCA) was also applied in this study to confirm that appropriate coating materials for NO2 and CO were selected. Two dimension PCA scores plot showed good separation between NO2 and CO which implied that NO2 and CO can be distinguished clearly by the two-channel SAW sensor. In addition, an artificial neural network, using back propagation network (BPN), was also used to recognize NO2 and CO gases and it shows the distinction of these inorganic gases qualitatively by the two-channel SAW sensor with Ru3+/ crypand[2,2] and Zn2+/ crypatnd[2,2] coatings. The quantitative analysis for NO2 and CO were also studied by the multivariate multiple regression analysis.

    摘要 I Abstract II 目錄 III 圖目錄 VI 表目錄 X 第一章 緒論 1 1-1 化學感測器陣列( Chemical sensor array ) 1 1-1-1 化學感測器( Chemical sensor ) 1 1-1-2 化學感測器陣列( Chemical sensor array) 4 1-1-3 模式辨識技術(Pattern recognition technology) 14 1-2 主成份分析(Principal component analysis) 18 1-2-1 簡介 18 1-2-2 基本原理 20 1-2-3 主成份分析之應用 22 1-2-4 成份分數 24 1-3 類神經網路(Artificial neural network) 26 1-3-1 生物神經元 26 1-3-2 人工神經元 29 1-3-3 類神經網路分類 31 1-3-4 倒傳遞類神經網路 34 1-4 冠狀醚與大環胺醚( Crown ethers and cryptands ) 42 1-4-1 簡介( Introduction ) 42 1-4-2 分類及命名( Classify and nomenclature ) 44 1-4-3 大環胺醚錯合物( Cryptates ) 46 1-5 聲波感測器(Acoustic wave sensor) 47 1-5-1 壓電效應 47 1-5-2 各式聲波感測器 49 1-5-3 各類型聲波感測器比較 53 1-5-4 表面聲波特性 54 1-5-5 表面聲波氣相感測原理 59 1-6 實驗目的與動機 62 第二章 實驗部分 63 2-1 藥品及儀器 63 2-2 表面聲波元件處理 63 2-2-1 表面聲波元件 63 2-2-2 塗佈液配製 64 2-2-3 表面塗佈法 64 2-3 實驗系統 65 2-3-1 多頻道感測器介面設計 65 2-3-2 系統程式 67 2-3-3 靜相系統 67 2-3-4 動相系統 69 2-4 數據處理 70 2-4-1 主成分分析法 70 2-4-2 倒傳遞神經網路分析法 72 第三章 結果與討論 73 3-1 靜相感測系統 73 3-1-1 各頻道偵測訊號之比較 73 3-1-2 一氧化碳及二氧化氮之感應頻率變化情形 75 3-1-3 冠狀醚對感應頻率變化影響 78 3-1-4 冠狀醚錯合中陰離子對感應頻率變化的影響 78 3-1-5 冠狀醚錯合中陽離子對感應頻率變化的影響 81 3-1-6 主成份分數散佈圖 87 3-1-7 表面塗佈量感應頻率變化的影響 89 3-1-8 濃度效應對感應頻率變化的影響 93 3-1-9 表面聲波感測器之再現性 97 3-1-10 溫度效應對感應頻率變化的影響 100 3-1-11 濕度效應對感應頻率變化的影響 105 3-1-12 有機干擾物對感應頻率變化的影響 112 3-1-13 揮發性有機污染物干擾效應 112 3-1-14 石英微量天平與表面聲波感測器之比較 117 3-1-15 表面聲波感測器之使用壽命 117 3-2 動相感測系統 122 3-2-1 動相系統感測頻率變化情形 122 3-2-2 動相系統待測物濃度效應 122 3-3 倒傳遞類神經辨識單一氣體 127 3-3-1 倒傳遞類神經網路參數設定 128 3-3-2 單一氣體之定性分析 133 3-3-3 單一氣體之定量分析 137 3-4 倒傳遞類神經辨識混合氣體 138 3-4-1 倒傳遞類神經網路參數設定 139 3-4-2 混合氣體之定性分析 143 3-4-2 混合氣體之定量分析 147 第四章 結論 149 參考文獻 151

    1. http://www.chem.qmu1.ac.uk/iupac/
    2. Janata, J.; Bezegh, A., Anal Chem., 1988, 60, 62R
    3. Diamond, D., Principles of chemical and biological sensors, John Willy & Sons, 1998
    4. Mitrovics, J.; Ulmer, H.; Weimar, U.; Gopel, W., Modular Sensor Systems for Gas Sensing and Odor Monitoring: The MOSES Concept, Acc. Chem. Res., 1998, 31, 307-315.
    5. Sauerbery, G. Z., Phys., 1959, 155, 206
    6. Janata, J.; Josowicz, M., Chemical Sensors, Anal. Chem., 1998, 70, 179R-208R
    7. Janata, J., Centennial Retrospective on Chemical Sensors, Anal. Chem., 2001, 73, 150A-153A
    8. 伍秀菁;汪若文;林美吟, 微機電技術與應用, 國科會精儀中心, 2003
    9. Foote, R. S.; Khandurina, J.; Jacobson, S. C.; Ramsey, J. M., Preconcentration of Proteins on Microfluidic Devices Using Porous Silica Membranes, Anal. Chem., 2005, 77, 57-63
    10. Perez, G. P.; Crooks, R. M., Pore-Bridging Poly(dimethylsiloxane) Membranes as Selective Interfaces for Vapor-Phase Chemical Sensing, Anal. Chem., 2004, 76, 4137-4142
    11. Henry, C. S.; Fritsch, I., Microfabricated Recessed Microdisk Electrodes: Characterization in Static and Convective Solutions, Anal. Chem., 1999, 71, 550-556
    12. Kong, J.; Franklin, N. R.; Zhou, C. W.; Chapline, M. G.; Peng, S.; Cho, K. J.; Dai, H., Nanotube Molecular Wires as Chemical Sensors, Science, 2000, 287, 622-625
    13. Erickson, D.; Liu, X.; Krull, U.; Li, D., Electrokinetically Controlled DNA Hybridization Microfluidic Chip Enabling Rapid Target Analysis, Anal. Chem., 2004, 76, 7269-7277
    14. Campbell, R., Biology, 6th, Benjamin Cummings, 2002
    15. Albert, K. J.; Lewis, N. S.; Schauer, C. L.; Sotzing, G. A.; Stitzel, S. E.; Vaid, T. P.; Walt, D. R., Cross-Reactive Chemical Sensor Arrays, Chem. Rev., 2000, 100, 2595-2626
    16. Stankova, M.; Ivanov, P.; Llobet, E.; Brezmes, J.; Vilanova, X.; Grcia, I.; Can, C.; et. al., Sputtered and screen-printed metal oxide-based integrated micro-sensor arrays for the quantitative analysis of gas mixtures, Sens. Actuators B, 2004, 103, 23-30
    17. Llobet, E.; Ivanov, P.; Vilanova, X.; Brezmes, J.; Hubalek, J.; Malysz, K.; Grcia, I., Screen-printed nanoparticle tin oxide films for high-yield sensor microsystems, Sens. Actuators B, 2003, 96, 94-104
    18. Floyd., Electronics fundamentals circuit, device, and application. 6th, Pearson Prentice Hall, 2004
    19. Eklov, T.; Lundstrom, I., Distributed Sensor System for Quantification of Individual Components in a Multiple Gas Mixture, Anal. Chem., 1999, 71, 3544-3550
    20. Lonergan, M. C.; Severin, E. J.; Doleman, B. J.; Beaber, S. A.; Grubbs, R. H.; Lewis, N. S., Array-Based Vapor Sensing Using Chemically Sensitive, Carbon Black-Polymer Resistors, Chem. Mater., 1996, 8, 2298-2312
    21. White, J.; Kauer, J. S.; Dickinson, T. A.; Walt, D. R., Rapid Analyte Recognition in a Device Based on Optical Sensors and the Olfactory System, Anal. Chem., 1996, 68, 2191-2202
    22. Chen, Q.; Wang, J., Rayson, G.; Tian, B.; Lin. Y., Sensor array for carbohydrates and amino acids based on electrocatalytic modified electrodes, Anal. Chem., 1993, 65, 251-254
    23. Lin, H. B.; Shih, J. S., Fullerene C60-cryptand coated surface acoustic wave quartz crystal sensor for organic vapors, Sens. Actuators B, 2003, 92, 243-254
    24. Chang, P.; Shih, J. S., Multi-channel piezoelectric quartz crystal sensor for organic vapours, Anal. Chim. Acta, 2000, 403, 39–48
    25. Jurs, P. C.; Bakken, G. A.; McClelland, H. E., Computational Methods for the Analysis of Chemical Sensor Array Data from Volatile Analytes, Chem. Rev., 2000, 100, 2649-2678
    26. 盧炳勳; 曹登發, 類神經網路理論與應用, 全華科技圖書, 1992
    27. 張健邦, 應用多變量分析, 文富出版社, 1993
    28. 黃俊英, 多變量分析 7th , 華泰文化, 2000
    29. 陳正昌; 程炳林; 陳新豐; 劉子鍵, 多變量分析方法-統計軟體應用, 五南圖書, 2003
    30. 葉怡成, 類神經網路模式應用與實作, 儒林圖書, 2000
    31. 蔡瑞煌, 類神經網路概論, 三民書局, 1995
    32. Cooley, W. W.; Lohnes, P. R., Multivariate data analysis, John Wiley& Sons, 1971
    33. Person, Philosophy Magazine, 1901, 6, 559-572
    34. Hotelling, H., Analysis of a Complex of Statistical Variables into Principal Components, Journal of Education Psychology, 1933, 24, 417-441
    35. Hotelling, H., Relations Between two Sets of Variates, Biometrika, 1936, 28, 321-337
    36. 林清山, 多變項分析統計法, 東華書局, 1993
    37. 何培基, SAS/PC入門與語言手冊, 松岡電腦圖書, 1988
    38. 林傑斌; 陳湘; 劉明德, SPSS11統計分析實務設計寶典, 博碩文化, 2002
    39. Ha, S. C.; Kim, Y. S.; Yang, Y.; Kim, Y. J.; Cho, S. M.; Yang, H., Integrated and microheater embedded gas sensor array based on the polymer composites dispensed in micromachined wells, Sens. Actuators B, 2005, 105, 549-555
    40. Santos, J.P.; Arroyo, T.; Aleixandre, M.; Lozano, J.; Sayago, I.; Garca, M.; Fernndez, M.J., A comparative study of sensor array and GC–MS: application to Madrid wines characterization, Sens. Actuators B, 2004, 102, 299-307
    41. 戴汝為, 人工智慧, 五南圖書, 2003
    42. Haykin, S., Neural network: a comprehensive function, Macmillan College Publishing Company, 1994
    43. 林昇甫; 洪成安, 神經網路入門與圖樣辨識, 全華科技圖書, 1999
    44. 傅心家, 神經網路導論, 定碁科技, 1991
    45. 郭益銘, 應用多變量統計與類神經網路分析雲林沿海地區地下水水質變化, 國立台灣大學農業工程研究所碩士論文, 1999
    46. 張平, 有機氣體石英壓電晶體感測器的研製與應用, 國立台灣師範大學化學所博士論文, 2000
    47. Gokel, G.., Crown ethers & cryptands, Royal Society of Chemistry, 1991
    48. Lehn, J. M., Cryptates: the chemistry of macropolycyclic inclusion complexes, Acc. Chem. Res., 1978, 11, 49-57
    49. Lu, C.; Czanderna, C. A. W., Application of Piezoelectric Quartz Crypstal Microbalance, Elservier Science, 1984
    50. 吳朗, 壓電陶瓷-壓電, 全欣科技圖書, 1994
    51. 吳朗, 感測與轉換原理、元件與應用, 全欣科技圖書, 1992
    52. Michael, J. V., Acoustic wave sensors and their technology, Ultrasonics, 1998, 36, 7-14
    53. Zemel, J. M., Rev. Sci. Instrum., 1990, 61, 1579
    54. Martin, S. J.; Ricco, A. J.; Niemczyk, T. M.; Frye, G. C., Sens. Actuators, 1989, 20, 253-268
    55. Wenzel, S. W., Applications of Ultrasonic Lamb Waves, Dostoral Dissertation, EECS Department, University of California, Berkeley, CA, 1992
    56. Bruno, P.; Cicala, G.; Corsi, F.; Dragone, A.; Losacco, A.M., High relative humidity range sensor based on polymer-coated STW resonant device, Sens. Actuators B, 2004, 100, 126-130
    57. Ollivier, T. C.; Corinne De´jousa; Dominique Rebie`rea; Jacques Pistre´a; Sylvie Comeaub; Daniel Moynetc; Jean Bezian., Study of acoustic Love wave devices for real time bacteriophage detection, Sens. Actuators B, 2003, 91, 275–284
    58. Rayleigh, L.; Voltmer, F. W., Direct Piexoelectric Coupling to Surface Elastic Waves, Apply. Phys. Lett., 1965, 7, 314-316
    59. Ballantine, D. S.; White, R. M.; Martin, S. J.; Wohltjen, H.; Zellers, E. T., Acoustic Wave Sensors Theory design and physico-chemical application, Academic press, 1997
    60. Wohltjen, H., Mechanism of Operation and Design Considerations for Surface Acoustic Wave Device Vapor Sensors, Sens. Actuators, 1984, 5, 307-325
    61. Morgan, D., Surface-Wave Device for Signal Processing, Amsterdam, 1991, 152
    62. Wohltjen, H.; Dessy, R., Surface acoustic wave probe for chemical analysis. I. Introduction and instrument description, Anal. Chem., 1979, 51, 1458-1464
    63. Lewis, M. F., Surface Acoustic Wave devices and Applications 6. Oscillators-the next successful surface acoustic wave device, Ultrasonics, 1974, 12, 115-123
    64. Ash, E. A., Acoustic Aurface Wave, Speringer-Verlag, New York, 1978
    65. Auld, B. A., Acoustic Fields and Waves in Solids, 2nd, Wiley-Interscience, New York, 1973
    66. Pedersen, C. J., Cyclic polyethers and their complexes with metal salts, J. Am. Chem. Soc., 1967, 89, 7017-7036
    67. Allen, J. B.; Larry, R.F., Electrochemical Methods Fundamentals and Applications, 2nd, John Wiley & Sons. Inc, 2001
    68. 彭成鑑, 壓電材料, 科儀新知, 1995, 16, 18-29
    69. http://www.epa.gov.tw/main/index.asp
    70. http://www.e-safety.com.tw/2_main/206_msds_2/search.htm
    71. http://www.yoketant.com.tw/
    72. http://www.wenshing.com.tw/
    73. 周鈺禎, 雙頻道表面聲波感測系統研製與應用, 國立台灣師範大學化學所碩士論文, 2005

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