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11رسالة جامعية
المؤلفون: 管俊亭, Kuan, Chun-ting
المساهمون: 李慧梅, 臺灣大學:環境工程學研究所
مصطلحات موضوعية: 懸浮微粒, 空氣負離子(NAI), 奈米碳管, 相對濕度, ECR, suspended particulate, negative air ion (NAI), carbon nanotube, relative humidity
وصف الملف: 3133118 bytes; application/pdf
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Sergey, “ Removal of Fine and Ultrafine Particles from Indoor Air Environments by the Unipolar Ion Emission,” Atmospheric Environment, 38, 4815-4823 ( 2004 ) Liu, C., Y.Y. Fan, M. Liu, H.T. Cong, H.M. Cheng, and M.S. Dresselhaus,“ Hydrogen Storage in Single-walled Carbon Nanotubes at Room Temperature,” Science, 286, 1127 ( 1999 ) Luts, A., “ Evolution of Negative Small Ions at Enhanced Ionization,”Journal of Geophysical Reserch, 100(D1), 1487-1496 ( 1995 ) Matsumoto, K., S. Kinosita, and Y. Gotoh, “ Ultralow Biased Field Emitterusin Using Single-wall Carbon Nanotube Directly Grown onto Silicon Tip by Thermal Chemical Vapor Deposition,” Applied Physics letters, 78, 539 ( 2001 ) Mayya, Y.S., B.K. Sapra, A. Khan, and F. Sunny, ” Aerosol Removal by Unipolar Ionization in Indoor Environments,” Journal of Aerosol Science, 35, 923-941 ( 2004 ) Mizuno, K., K. Hata, T. Saito, S. Ohshima, M. Yumura, and S. Iijima,“ Selective Matching of Catalyst Element and Carbon Sources in Single-Walled Carbon Nanotube Synthesis on Silicon Substrates,”J.Phys. Chem. B, 109, 2632 ( 2005 ) Offermann, F.J., R.G. Sextro, W.J. Fisk, D.T. Grimsrud, W.W. Nazaroff, A.V. Nero, K.L. Revzan, and J. Yater, “ Control of Respirable Particles in Indoor Air with Portable Air Cleaners,” Atmospheric Environment, 19, 1761-1771 ( 1985 ) Modi, A., N. Koratkar, E. Lass, B. Wei and P.M. Ajayan, “ Miniaturized Gas Ionization Sensors Using Carbon Nanotubes,” Nature, 424, 171 ( 2003 ) Pan, Z.W., S.S. Xie, B.H. Chang, L.F. Sun, W.Y. Zhou, and G. Wang,“ Direct Growth of Aligned Open Carbon Nanotubes by Chemical Vapor Deposition,” Chemical Physics Letters, 299, 97 ( 1999 ) Park, S.H., H.O. Kim, Y.T. Han, S.B. Kwon and K.W. Lee, ” Wall Loss Rate of Polydispersed Aerosols,” Aerosol science and technology, 35,710-717 ( 2001 ) Popov, V.N., “ Carbon Nanotubes: Properties and Application,” Report: A Review Journal, 43, 61 ( 2004 ) Rinzler, A.G., J.H. Hafner, P. Nikolaev, L. Lou, S.G. Kim, D. Tomanek, P. Nordlander, D.T. Colbert and R.E. Smalley, “ Unraveling Naotubes: Field Emission from an Atomic Wire,” Science, 269, 1550 ( 1995 ) Shun Cheng Lee,” Indoor Air Quality at Restaurants with Different Styles of Cooking in Metropolitan Hong Kong,” The Science of the Total Environment , 279, 181 ( 2001 ) Siegmann, K. and K. Sattler, “ Aerosol from Hot Cooking Oil, A possible Health Hazard,” J. Aerosol Science, 27, 493 ( 1996 ) Skalny, J.D., T. Mikoviny, S. Matejcik and N.J. Mason, “ An Analysis of Mass Spectrometric Study of Negative Ions Extracted from Negative Corona Discharge in Air,” International Journal of Mass Spectrometry, 233, 317-324 ( 2004 ) Smirnov, B.M., Cluster Ions and Van der Waals Molecules. Gordon and Breach, Philiadephia ( 1992 ) Song, J., M. Sun, Q. Chen, J. Wang, G. Zhang, and Z. Xue, “ Field Emission from Carbon Nanotube Arrays Fabricated by Pyrolysis of Iron Phthalocyanine,” J.Phys.D: Appl. Phy., 37, 5 ( 2004 ) Tzeng, Y., Y. Chen, N. Sathitsuksanoh, and C. Liu, “ Electrochemical Behaviors and Hydration Properties of Multi-wall Carbon Nanotube Coated Electrodes in Water,” Diamond and Related Materials, 13,1821-1826 ( 2004 ) Wallace, L.A., S.J. Emmerich, and C. Howard-Reed, “ Effect of Central Fans and In-duct Filters on Deposition Rates of Ultrafine and Fine Particles in an Occupied Townhouse,” Atmospheric Environment, 38, 405-413 ( 2004 ) Wang, Y., Z. Iqbal and S. Mitra, “ Rapid, Low Temperature Microwave Synthesis of Novel Carbon Nanotube-silcon Carbide Composite,”Carbon, 44, 2804-2808 ( 2006 ) Wu, C.C., W.M. Lee, P. Cheng, S. Yang, and K.P. Yu “ Effect of Wall Surface Materials on Deposition of Particles with the Aid of Negative Air Ions,” Journal of Aerosol Science, 37, 616-630 ( 2006 ) Wu, C.C., W.M. Lee, P. Cheng, S. Yang, K.P. Yu and C.L. Lou “ Influence of Air Humidity and the Distance from the Source on Negative Air Ion Concentration in Indoor Air,” Science of the Total Environment, 370,245-253 ( 2006 ) Yu, J., J. Lucas, V. Strezov and T. Wall, “ Coal and Carbon Nanotube Production,” FUEL, 82, 2025 ( 2003 ) Zhang, Y. and S. Iijima, “ Elastic Response of Nanotube Bundle to Visible Light,” Physical Review Letters, 82, 3472 ( 1999 ) 李建坤,”拜香及蚊香燃燒產生之多環芳香烴化合物”,碩士論文,台大公共衛生學研究所,1996 劉美娟,”電蚊香片釋放物之探討”,碩士論文,台大職業醫學與工業衛生研究所,1996 張西川,家庭醫學圖書館 - 呼吸系統,光復書局企業股份有限公司,1996 高玫鍾、龍世俊,”燒香對居家室內PM10 濃度影響之研究”,氣膠科技國際研討會論文集,280~286 頁,1999 楊心豪,”噴霧劑室內氣膠吸濕成長之研究”,碩士論文,台大環境工程學研究所,2000 王秋森、陳時欣,氣膠技術學,新文京開發出版有限公司,2002 李世銘,”聚醯亞胺-黏土奈米複合材料之製備與其介電特性之研究”,碩士論文,中原大學化學系,2004 成會明,奈米碳管 Carbon Nanotubes,五南圖書出版股份有限公司,2004 鄭博仁,”空氣負離子對室內懸浮微粒去除效率之研究”,碩士論文,台大環境工程研究所,2004 室內空氣品質建議值,行政院環保署,2005 孫浩仁,”室內材質表面特性對空氣負離子去除懸浮微粒效率之影響”, 碩士論文,台大環境工程研究所,2006 吳致呈,”空氣負離子控制室內空氣污染物之研究”,博士論文,台大環境工程研究所,2006; zh-TW; http://ntur.lib.ntu.edu.tw/handle/246246/62631Test; http://ntur.lib.ntu.edu.tw/bitstream/246246/62631/1/ntu-96-R94541105-1.pdfTest
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12رسالة جامعية
المؤلفون: 王榮德, Wang, Rung-De
المساهمون: 吳政忠, 臺灣大學:應用力學研究所
مصطلحات موضوعية: 表面聲波, 無線, 被動式, 阻抗, 相對濕度, 聚苯胺, 奈米纖維, Surface acoustic wave, Wireless, Passive, Impedance, Relative humidity, Polyaniline, Nanofiber
وصف الملف: 2581970 bytes; application/pdf
العلاقة: 1. Tsuneharu Nitta, Jiro Terada, and Fumio Fukushima. “Multifunctional Ceramic Sensors: Humidity-Gas Sensor and Temperature-Humidity Sensor, ” IEEE Transactions on Electron Devices, pp. 95-101 (1982) 2. Sung-Pil Lee, Jung-Yup Cha, Yeo-Kyung Yoon, and Seong-Jeen Kim. “FET HUMIDITY SENSORS BASED ON TITANIUM OXIDE FILM,” Proceedings of the 5th International Conference on Properties and Applications of Dielectric Materials, pp. 1066-1069 (1997) 3. Masanobu Matsuguch, Takaaki Kuroiwa, Tetsuya Miyagishi, Sachiko Suzuki, Tsutomu Ogura, and Yoshiro Sakai. “Stability and reliability of capacitive-type relative humidity sensors using crosslinked polyimide films,” Sensors and Actuators B, vol. 52, pp. 53-57 (1998) 4. Kyoko Yatsuzuka, Yoshio Higashiyama, and Kazutoshi Asano. “Fundamental Characteristics of Hydrophilic Polymer (Polyether Block Amide) as a Humidity Sensor,” Japanese Journal of Applied Physics, vol. 32, pp. 461-463 (1993) 5. U.S.SENSOR, “U.S. Sensor Catalog,” http://www.ussensor.comTest 6. Marshall Brain. “How Thermometers Work,” http://home.howstuffworks.comTest 7. Roberto Roubicek, “Temperature Profiling using a BOLLERWATCH® SP Acoustic Gas Pyrometer System On a Delay Coker,” http://www.sciengr.com/spanish/download_literature/downloads/800953.pdfTest 8. Hyung-Kew Lee, Jun-Bo Yoon and Euisik Yoon, “A High Fill-Factor IR Bolometer Using Multi-Level Electrothermal Structures,” IEEE International Electron Devices Meeting, pp. 463-466 (1998) 9. Leonhard M. Reindl and Ismail M. Shrena, “Wireless Measurement of Temperature Using Surface Acoustic Waves Sensors,” IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, pp. 1457-1463 (2004) 10. White, R. M. and Voltmeter, F. W., “Direct Piezoelectric Coupling to Surface Elastic Waves,” Applied Physics Letter, vol. 7, pp. 314-316 (1965) 11. Cole, P. H. and Vaughn R., “ELECTRONIC SURVEILLANCE SYSTEM,” United States Patent 3755803 (1973) 12. Bao, X. Q., Burkhard, W., Varadan, V. V. and Varadan, V. K. “SAW temperature sensor and remote reading system,” IEEE Ultrasonics Symposium, pp. 583-585 (1999) 13. K. Yamanouchi, G. Shimizu, and K. Morishita, “2.5GHz SAW Propagation and Refltion Characteristics and Application to Passive Electronic Tag and Matched Filter,” IEEE Ultrasonics Symposium, pp 1267-1270 (1993) 14. Reinhard Steindl, Alfred Pohl, and Franz Seifert, “Impedance Loaded SAW Sensors Offer a Wide Range of Measurement Opportunities,” IEEE Transactions on Microwave Theory and Techniques, vol. 47, pp. 2625-2629 (1999) 15. Gernot Schimetta, Franz Dollinger, and Robert Weigel, “A Wireless Pressure-Measurement System Using a SAW Hybrid Sensor,” IEEE Transactions on Microwave Theory and Techniques, vol. 48, pp. 2730-2735 (2000) 16. S. A. Krutovertsev, O. M. Ivanova, and S. I. Sorokin, “Sensing Properties of Polyaniline Films Doped with Dawson Heteropoly Compounds,” Journal of Analytical Chemistry, vol. 56, pp. 1057-1060 (2001) 17. Shabnam Virgi, Jiaxing Huang, Richard B. Kaner, and Bruce H. Weiller, “Polyaniline Nanofiber Gas Sensors: Examination of Response Mechanisms,” Nano Letters, vol. 4, pp. 491-496 (2004) 18. Shabnam Virgi, Richard B. Kaner, and Bruce H. Weiller, “Hydrogen Sensors Based on Conductivity Changes in Polyaniline Nanofibers,” Journal of Physical Chemistry B, vol.110, pp. 22266-22270 (2006) 19. Abbott, B. P., “A Coupling-of-Modes Model For SAW Transducers With Arbitrary Reflectivity Weighting,” Ph.D dissertation, the Department of Electrical Engineering at the University of Central Florida Orlando, Florida. (1989) 20. Abbott, B. P., Hartmann, C. S. and Malocha, D. C. “A Coupling-of-Modes Analysis of Chirped Transducers Containing Reflective Electrode Geometries,” IEEE Ultrasonics Symposium, pp. 129-134 (1989) 21. Abbott, B. P., “A Derivation of the Coupling-of-Modes Parameters Based on the Scattering Analysis of SAW Transducers and Gratings,” IEEE Ultrasonics Symposium, pp. 5-10 (1991) 22. Abbott, B. P., Hartmann, C. S. and Malocha, D. C., “Transduction Magnitude and Phase for COM Modeling of SAW Devices,” IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, vol. 39, pp. 54-60 (1992) 23. Shiu, C. M., “UHF Band SAW Based RFID Sensor System,” Master thesis, Institute of Applied Mechanics, National Taiwan University, Taipei, Taiwan. (2005) 24. Hua Bai and Gaoquan Shi, “Gas Sensors Based on Conducting Polymers,” Sensors, vol. 7, pp. 267-307 (2007) 25. Abu Z. Sadek, Christina O. Baker, David A. Powell, Wojtek Wlodarski, Richard B. Kaner, and Kourosh Kalantar-zadeh, “Polyaniline Nanofiber Based Surface Acoustic Wave Gas Sensors-Effect of Nanofiber Diameter on H2 Response,” IEEE Sensors Journal, vol. 7, pp. 213-218 (2007) 26. Alan G. MacDiarmid, “Synthetic metals: a novel role for organic polymers,” Synthetic Metals, vol. 125, pp. 11-22 (2002) 27. Relative humidity: http://en.wikipedia.org/wiki/Relative_humidityTest 28. Jiaxing Huang, Shabnam Virgi, Bruce H. Weiller, and Richard B. Kaner, “Polyaniline Nanofibers: Facile Synthesis and Chemical Sensors,” Journal of the American Chemical Society, vol. 125, pp. 314-315 (2003); en-US; http://ntur.lib.ntu.edu.tw/handle/246246/62535Test; http://ntur.lib.ntu.edu.tw/bitstream/246246/62535/1/ntu-96-R94543020-1.pdfTest
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13رسالة جامعية
المؤلفون: 謝宗勳, Hsieh, Tsung-Hsun
المساهمون: 方煒, 臺灣大學:生物產業機電工程學研究所
مصطلحات موضوعية: 無線感測網路, 溫度, 濕度, 光合作用有效光, 總輻射能, ZigBee, Tmote Sky, Wireless Sensor Network, Temperature, Relative humidity, PAR, TSR
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14رسالة جامعية
المؤلفون: 楊心豪, Yang, Shin-Hao
المساهمون: 李慧梅, 臺灣大學:環境工程學研究所
مصطلحات موضوعية: 帶電濾材, 界面活性劑, 穿透率, 表面風速, 介電常數, 相對濕度, 微粒載負, 阻塞點, 生物氣膠, electret, surfactant, aerosol penetration, face velocity, dielectric constant, relative humidity, aerosol loading, clogging point, bioaerosol
وصف الملف: 1119401 bytes; application/pdf
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