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1دورية أكاديمية
المؤلفون: Yi Ren, Hua-Jie Zhu, Jie Ren, San-Yan Chu
المساهمون: 儲三陽
مصطلحات موضوعية: chemical exchanges, density functional theory, isomerisation, isomerism, organic compounds, reaction kinetics
الوقت: 31
العلاقة: Journal of Molecular Structure Theochem, Elsevier, Volume 730, Issue 1-3, OCT 7 2005, Pages 199-205; http://nthur.lib.nthu.edu.tw/dspace/handle/987654321/57766Test
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المؤلفون: 鄭傑仁, Jie-Ren Zheng
المساهمون: 葉孟考, Meng-Kao Yeh
مصطلحات موضوعية: 共振腔, 頻率飄移, cavity, frequency drift
الوقت: 28
وصف الملف: 155 bytes; text/html
العلاقة: 參考文獻 1. 羅國輝、王兆恩、張隆海與林明泉, “同步輻射儲存環之低溫超導共振腔簡介,” 同步輻射研究中心簡訊, No. 46, pp. 14-19, 2000. 2. H. Padamsee, “The Science and Technology of Superconductuing Cavity for Accelerators,” Superconducting Science and Technology, Vol. 14, pp. 28-51, 2001. 3. M. G. Rao and P. Kneisel, “Thermal and Mechanical Properties of Electron Beam Welded and Heated-Treated Niobium for Tesla,” Continuous Electron Beam Accelerator Facility Newport News﹐pp. 1-7, 1993. 4. E. Chiaveri, C. Benvenuti, R. Cosso, D. Lacarrere, K. M. Schirm, M. Taufer and W. Weingarten, “Analysis and Result of The Industrial Production of The Superconducting Nb/Cu Cavities for The LEP 2 Project,” Proceedings of The Particle Accelerator Conference, Dallas, Vol. 3, pp.1509-1511, 1995. 5. K. Saito, T. Fujino, H. Inoue, N. Hitomi, E. Kako, T. Shishido, S. Noguchi and Y. Yamazaki, “Feasibity Study of Nb/Cu Clad Sperconducting RF Cavities,” Superconducting, Vol. 9, No. 2, June, 1999. 6. Y. C. Tsai, “Studies of High Order Mode Suppression in Storage Ring RF Cavity,” Ph.D. Dissertation, National Tsing Hua University, 1997. 7. 戴英俠, “開口式共振腔場能頻譜特性探討,” 國立清華大學碩士論文, 1998. 8. 陳家逸,”高頻共振腔高次模抑制方法之研究,” 國立清華大學碩士論文, 2003. 9. 林保安, “開口式共振腔之特性探討,” 國立清華大學碩士論文, 1999. 10. 鍾明忠, ”共振腔結構受端面位移影響之模態分析與實驗,” 國立清華大學碩士論文, 2004. 11. 陳伯毅, ”低溫超導共振腔之挫曲及變形分析與實驗,” 國立清華大學碩士論文, 2003. 12. A. Lwabuchi, T. Shimize, Y. Yoshino, T. Abe, K. Katagiri, I. Nitta and K. Sadamori, “The Development of A Vickers-Type Hardness Tester for Cryogenic Temperatures down to 4.2 K, “Cryogenics, Vol. 36, No. 2, pp. 75-81, 1996. 13. N. Suzuki, T. Uchida and K. Suzuki, “Test Method and Strength Characteristics of Alumina Ceramics at Cryogenic Temperature,” Cryogenics, Vol. 38, No. 4, pp. 363-366, 1998. 14. Y. Yamaguchi, K. Horiguchi, Y. Shindo, D. Sekiya and S. Kumagai, “Fracture and Deformation Properties of Ni-Fe Superalloy in Cryogenic High Magnetic Field Environments,” Cryogenics, Vol. 43, pp. 469-475, 2003. 15. S. Ochiai, S. Nishino and K. Osamura, “Nb3Sn Tensile Strength and its Distribution Estimated from Change in Superconducting Critical Current of Preloaded Multifilamentary Composite Wire,” Cryogenics , Vol. 35, No. 1, pp. 55-60, 1995. 16. A. Nyilas, K. Osumera, and M. Sugano, “Mechanical and Physical Properties of Bi-233 and Nb3Sn Superconducting Materials Between 300K and 7K,” Superconducting Science and Technology, Vol. 16, pp. 36-42, 2003. 17. S. Awaji, K. Watanabe and K. Katagiri , “Improvement of Mechanical and Superconducting Properties in CuNb/(Nb,Ti)3Sn Wires by Applying Bending Strain at Room Temperature,” Superconductor Science and Technology, Vol. 16, pp. 733-738, 2003. 18. K. Mukugi, N. Ouchi, JAREI and Y. Morimoto, “Low Temperature Mechanical Properties of Titanium and Weld Joints(Ti/Ti,Ti/Nb) for Helium Vessels, ” SRF 2001 Proceeding﹐PT008, 2001. 19. K. Ishio, K. Kikuchi, M. Mizumoto and A. Naito, “Fracture Toughness and Mechanical Properties of Pure Niobium and its Welded Jionts of Superconducting Cavity at 4K,” 9th Workshop on RF Superconductivity 1999. 20. R. P. Walsh, R. R. Mitchell,V. T. Toplosky and R. C. GentZlinger, “Low Temperature Tensile and Fracture Toughness Properties of SCRF Cavity Structural Materials,” 9 th Workshop on RF- Superconductivity 1999. 21. D. C. Vander, W. Park and M. R. Hilton, “Characterization of Cryogenic Mechanical Properties of Aluminum-Lithium Alloy C-458,” Scripta Materialia, Vol. 41,No. 11, pp. 1185-1190, 1999. 22. C. Compton, T. Bieler, B. Simkin and S. Jadhav, “Measured Properties of High RRR Niobium,” Report of National Superconducting Cyclotron Laboratory, August 9, 2000. 23. M. G. Rao and P. Kneisel, “Mechanical Properties of High RRR Niobium at Cryogenic Temperature,” Advances in Cryogenic Engineerings, Vol. 40, pp.1383-1390, 1994. 24. B. Stephan, “Supplement of Worksheets and Useful Datas, ”Short course in cryogenics at SRRC﹐A-6.1-6.3, 1999. 25. M. F. Thomas, “Cryogenic Engineering,” Marcel Dekker Inc﹐pp. 181-214, 1997. 26. S. Belomestnykh, “Caculations of The Frequency Shift due to B-Cell Cavity Shape Deformation,” Report of SRF-940330-02, Cornell University, Ithaca, NY, 1994. 27. J. Kirchgessner and S. Belomestnykh, “On The Pressure Compensation for The B-Cell Cavity in The MARK II Cryostat,” Report of SRF-970624-06, Laboratory of Nuclear Studies, Cornell University, pp.1-4, 1997. 28. J. Kirchgessner, “Thoughts on The Very High Value of dF/dP or Pressure Sensitivity of The B Cell Cavity in The MTM Cryostat,” Report of SRF-940321-01, Laboratory of Nuclear Studies, Cornell University, 1994. 29. 高福聲, ”低溫超導共振腔之結構變形對內建電磁場特性之探討,” 國立清華大學碩士論文, pp. 1-35, 2002. 30. M. C. Lin, Ch. Wang, L. H. Chang and G. H. Luo, “Effect of Material Properties on Resonance Frequency of CESR-ΙΙΙ Type 500 Mhz SRF Cavity, ” Proceedings of the 2001 Particle Acceleration Conference﹐ pp. 1371-1374, 2004. 31. M. C. Lin, Ch. Wang, L. H. Chang, G. H Luo, F. S. Gao, M. K. Yeh and M. J. Huang, “A Coupled-Field Analysis on a 500 MHz Superconducting Radio Frequency Niobium Cavity,” Proceedings of EPAC 2002, Paris, France, pp. 2259-2261, 2002. 32. D. K. Cheng, “ Field and Wave Electromagnetic,” Addison Wesley, New York, 1989. 33. ANSYS Element Reference. 000855. Eighth Edition. SAS IP, Inc. 1997. 34. ANSYS Theory Reference. 000855. Eighth Edition. SAS IP, Inc. 1997 35. J. Jin, “The Finite Element Method in Eletromagnetics,” Wiley-Interscience, New York,1993. 36. ASTM B557-81, “Standard Test Method for Tension Test of Metallic Material,” Annual Book of ASTM Standards, Section 2, Vol. 02.02., pp.561-567. 37. A. C. Ugural and S. K. Fenster, “Advanced Strength and Applied Elasticity,” Fourth Edition, pp. 314-335, 2003. 38. 許世壁, “非線性聯立方程式數值方法,” 中央圖書出版社, 1988. 39. R. L. Branham, “Scientific Data Analysis: An Introduction to Overdetermined Systems,” Springer-Verlag, New York, 1990.; http://nthur.lib.nthu.edu.tw/dspace/handle/987654321/28904Test
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المؤلفون: 鄭傑仁, Jie-Ren Zheng
المساهمون: 葉孟考, Meng-Kao Yeh
مصطلحات موضوعية: 共振腔, 頻率飄移, cavity, frequency drift
الوقت: 28
وصف الملف: 2560191 bytes; application/octet-stream
