桿狀病毒的偶極模態分析與其微波共振吸收量測

Yi-Chun Tsai; 蔡易浚

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/56631

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	孫啟光(Chi-Kuang Sun)
dc.contributor.author	Yi-Chun Tsai	en
dc.contributor.author	蔡易浚	zh_TW
dc.date.accessioned	2021-06-16T05:38:53Z	-
dc.date.available	2017-09-05
dc.date.copyright	2014-09-05
dc.date.issued	2014
dc.date.submitted	2014-08-12
dc.identifier.citation	[1.1]: H. Lamb, “On the Vibrations of an Elastic Sphere,” Proceedings of the London Mathematical Society, s1-13, pp.189 (1881). [1.2]: E. Duval, A. Boukenter and B. Champagnon, “Vibration eigenmodes and size of microcrystallites in glass: observation by very low frequency Raman scattering,” Physical Review Letters, Vol.56, pp.2052 (1986). [1.3]: E. Duval, “Far-infrared and Raman vibrational transitions of a solid sphere: Selection rules,” Physical Review B, Vol.46, pp.5795 (1992). [1.4]: D. B. Murray, C. H. Netting, L. Saviot, C. Pighini, N. Millot, D. Aymes, and H. L. Liu, “Far infrared absorption by acoustic phonons in titanium dioxide nanopowders,” Journal of Nanoelectronics and Optoelectronics, Vol.1, pp.92 (2006). [1.5]: T.-M. Liu, J.-Y. Lu, H.-P. Chen, C.C. Kuo, M.-J. Yang, C.-W. Lai, P.-T. Chou, M.-H. Chang, H.-L. Liu, Y.-T. Li, C.-L. Pan, S.-H. Lin, C.-H. Kuan, and C.-K. Sun, “Resonance-enhanced dipolar interaction between terahertz photons and confined acoustic phonons in nanocrystals,” Applied Physics Letters, Vol.92, 093122 (2008). [1.6]: S. Kim, B. Fisher, H.-J. Eisler, and M. Bawendi, “Type-II quantum dots: CdTe/CdSe (core/shell) and CdSe/ZnTe (core/shell) heterostructures” Journal of the American Chemical Society, Vol.125, pp.11466 (2003). [1.7]: T.-M. Liu, H.-P. Chen, L.-T. Wang, J.-R. Wang, T.-N. Luo, Y.-J. Chen, S.-I. Liu, and C.-K. Sun, “Microwave resonant absorption of viruses through dipolar coupling with confined acoustic vibrations,” Applied Physics Letters, Vol.94, 043902 (2009). [2.1]: H. Lamb, “On the Vibrations of an Elastic Sphere,” Proceedings of the London Mathematical Society, s1-13, pp.189 (1881). [2.2]: A. E. H. LOVE, A treatise on the mathematical theory of elasticity, New York Dover, Chapter XII, pp.279 (1944). [2.3]: A. Tamura, K. Higeta, and T. Ichinokawa, “Lattice vibrations and specific heat of a small particle,” Journal of Physics C: Solid State Physics, Vol.15, pp.4975 (1982). [2.4]: E. Duval, A. Boukenter, and B. Champagnon, “Vibration eigenmodes and size of microcrystallites in glass: observation by very low frequency Raman scattering,” Physical Review Letters, Vol.56, pp.2052 (1986). [2.5]: M. H. Kuok, H. S. Lim, S. C. Ng, N. N. Liu, and Z. K. Wang, “Brillouin study of the quantization of acoustic modes in nanospheres,” Physical Review Letters, Vol.90, 149901 (2003). [2.6]: T. D. Krauss and F. W. Wise, “Coherent Acoustic Phonons in a Semiconductor Quantum Dot,” Physical Review Letters, Vol.79, pp.5102 (1997). [2.7]: E. Duval, “Far-infrared and Raman vibrational transitions of a solid sphere: Selection rules,” Physical Review B, Vol.46, pp. 5795 (1992). [2.8]: D. B. Murray, C. H. Netting, L. Saviot, C. Pighini, N. Millot, D. Aymes, and H.-L. Liu, “Far infrared absorption by acoustic phonons in titanium dioxide nanopowders,” Journal of Nanoelectronics and Optoelectronics, Vol.1, pp.92 (2006). [2.9]: T.-M. Liu, J.-Y. Lu, H.-P. Chen, C.-C. Kuo, M.-J. Yang, C.-W. Lai, P.-T. Chou, M.-H. Chang, H.-L. Liu, Y.-T. Li, C.-L. Pan, S.-H. Lin, C.-H. Kuan, and C.-K. Sun, “Resonance-enhanced dipolar interaction between terahertz photons and confined acoustic phonons in nanocrystals,” Applied Physics Letters, Vol.92, 093122 (2008). [2.10]: S. Kim, B. Fisher, H.-J. Eisler, and M. Bawendi, “Type-II quantum dots: CdTe/CdSe (core/shell) and CdSe/ZnTe(core/shell) heterostructures,” Journal of the American Chemical Society, Vol.125, pp.11466 (2003). [2.11]: W. Grundler and F. Keilmann, “Sharp resonances in yeast growth prove nonthermal sensitivity to microwaves,” Physical Review Letters, Vol.51, pp.1214 (1983). [2.12]: T.-M. Liu, H.-P. Chen, L.-T. Wang, J.-R. Wang, T.-N. Luo, Y.-J. Chen, S.-I. Liu, and C.-K. Sun, “Microwave resonant absorption of viruses through dipolar coupling with confined acoustic vibrations,” Applied Physics Letters, Vol.94, 043902 (2009). [2.13]: J.-R. Wang, H.-P. Tsai, P.-F. Chen, Y.-J. Lai, J.-J. Yan, D. Kiang, K.-H. Lin, C.-C. Liu, and I.-J. Su, “An outbreak of enterovirus 71 infection in Taiwan, 1998. II. Laboratory diagnosis and genetic analysis,” Journal of Clinical Virology, Vol.17, pp.91 (2000). [2.14]: T. Noda, H. Sagara, A. Yen, A. Takada, H. Kida, R.H. Cheng, Y. Kawaoka, “Architecture of ribonucleoprotein complexes in influenza A virus particles,” Nature (London), Vol.439, pp.490 (2006). [2.15]: Y.-Y. Wen, T.-Y. Chang, S.-T. Chen, C. L., H.-S. Liu, “Comparative study of enterovirus 71 infection of human cell lines,” Journal of Medical Virology, Vol.70, pp.109 (2003). [2.16]: M. H. Sadd, Elasticity: Theory, Applications and Numerics, Elsevier Dordrecht, Chapter 8, pp.175 (2005). [3.1] L. Pochhammer, “Biegung des Kreiscylinders--Fortpflanzungs-Geschwindigkeit kleiner Schwingungen in einem Kreiscylinder,” Journal fur die reine und angewandte Mathematik, Vol.81, pp.326 (1876). [3.2] C. Chree, “Longitudinal vibrations of a circular bar,” The Quarterly Journal of Pure and Applied Mathematics, Vol.21, pp.287 (1886). [3.3] G. W. McMahon, “Experimental study of the vibrations of solid, isotropic elastic cylinders,” Journal of the Acoustical Society of America, Vol.36, pp.85 (1964). [3.4] J. R. Hutchinson, “Axisymmetric vibrations of a free finite length rod,” Journal of the Acoustical Society of America, Vol.51, pp 233 (1972). [3.5] J. R. Hutchinson, “Vibrations of solid cylinders,” Journal of Applied Mechanics American Society of Mechanical Engineers, Vol.47, pp.901 (1980). [3.6] H. R. Hamidzadeh and R. N. Jazar, Vibrations of Thick Cylindrical Structures, Springer New York Dordrecht Heidelberg London, pp.50 (2010). [3.7] A.E.H. LOVE, A treatise on the mathematical theory of elasticity, New York Dover (1944). [3.8] M. Hu, X. Wang, G. V. Hartland, P. Mulvaney, J. P. Juste, and J. E. Sader, “Vibrational Response of Nanorods to Ultrafast Laser Induced Heating: Theoretical and Experimental Analysis,” Journal of the American Chemical Society, Vol.125, pp.14925 (2003). [3.9] H. Lange, M. Mohr, M. Artemyev, U. Woggon, and C. Thomsen, “Direct Observation of the Radial Breathing Mode in CdSe Nanorods,” Nano Letters, Vol.8, pp.4614 (2008). [3.10] H.-P. Chen, Y.-C. Wu, P. A. Mante, S.-J. Tu, J.-K. Sheu, and C.-K. Sun, “Femtosecond excitation of radial breathing mode in 2-D arrayed GaN nanorods,” Optics Express, Vol.20, pp.16611 (2012). [3.11]A. Bayon, A.Varade, and F.Gascon, “On the acoustical longitudinal vibration modes of finite cylinder,” Journal of the Acoustical Society of America, Vol.96, pp.1539 (1994). [3.12] S. Ganci, “A simple experiment on flexural vibrations and Young’s modulus Measurement,” Physics Education, Vol.44, pp.239 (2009). [3.13] S. S. Rao, Vibration of Continuous Systems, John Wiley & Sons, pp.317 (2007). [3.14] B. Stephanidis, S. Adichtchev, P. Gouet, A. McPherson, and A. Mermet, “Elastic Properties of Viruses,” Biophysical Journal, Vol. 93, pp.1354 (2007). [3.15] I. L. Ivanovska, P. J. de Pablo, B. Ibarra, G. Sgalari, F. C. MacKintosh, J. L. Carrascosa, C. F. Schmidt, and G. J. L.Wuite, “Bacteriophage capsids: tough nanoshells with complex elastic properties,” Proceedings of the National Academy of Sciences of USA, Vol.101, pp.7600 (2004). [3.16] C. B. N. Jr, L. M. Tapay, and P. C. Loh, “Characterization of a non-occluded baculovirus-like agent pathogenic to penaeid shrimp,” Diseases of aquatic organisms, Vol.33, pp.221 (1998). [3.17] J. V. Stewart. Intermediate Electromagnetic Theory, World Scientific, Chapter 6, pp.340 (2001). [3.18] M. J. Fraser, “Ultrastructural Observations of Virion Maturation in Autographa californica Nuclear Polyhedrosis Virus Infected Spodoptera frugiperda Cell Cultures,” Journal of Ultrastructure and Molecular Structure Research, Vol.95, pp.189 (1986). [3.19] T. Vicente, C. Peixoto, P. M. Alves, and M. J. Carrondo, “Modeling electrostatic interactions of baculovirus vectors for ion-exchange process development,” Journal of Chromatography A, Vol.1217, pp.3754 (2010). [3.20] J.-M. Tsai, H.-C. Wang, J.-H. Leu, A. H.-J. Wang, Y. Zhuang, P. J. Walker, G.-H. Kou, and C.-F. Lo, “Identification of the Nucleocapsid, Tegument, and Envelope Proteins of the Shrimp White Spot Syndrome Virus Virion,” Journal of Virology, Vol.80, pp.3021 (2006). [3.21] K. Sritunyalucksana, W. Wannapapho, C. F. Lo and T. W. Flegel, “PmRab7 Is a VP28-Binding Protein Involved in White Spot Syndrome Virus Infection in Shrimp,” Journal of Virology, Vol.80, pp.10734 (2006). [3.22] Y.-S. Chang, W.-J. Liu, C.-C. Lee, T.-L. Chou, Y.-T. Lee, T.-S. Wu, J.-Y. Huang, W.-T. Huang, T.-L. Lee, G.-H. Kou, A. H.-J. Wang, and C.-F. Lo, “A 3D Model of the Membrane Protein Complex Formed by the White Spot Syndrome Virus Structural Proteins,” Public Library of Science One, Vol.5, pp.10718 (2010). [3.23] “WHITE SPOT DISEASE,” Manual of Diagnostic Tests for Aquatic Animals 2012, Chapter 2.2.6, pp.177 (2012). [3.24] M. C. W. van Hulten, M. Reijns, A. M. G. Vermeesch, F. Zandbergen and J. M. Vlak, “Identification of VP19 and VP15 of white spot syndrome virus (WSSV) and glycosylation status of the WSSV major structural proteins,” Journal of General Virology, Vol.83, pp.257 (2002). [4.1] S S Stuchly and C E Bassey, “Microwave coplanar sensors for dielectric measurements,” Measurement Science and Technology, Vol.9, pp.1324 (1998). [4.2] C. D. Abeyrathnea, M. N. Halgamuge, P. M. Farrell, and E. Skafidas, “Comparison of corrected calibration independent transmission coefficient method to estimate complex permittivity,” Sensors and Actuators A, Vol.189, pp.466 (2013). [4.3] T. Chretiennot, D. Dubuc, and K. Grenier, “A Microwave and Microfluidic Planar Resonator for Efficient and Accurate Complex Permittivity Characterization of Aqueous Solutions,” IEEE Transactions on Microwave Theory and Techniques, Vol.61, pp.972 (2013). [4.4] A. Raj, W. S. Holmes, and S. R. Judah, “Wide Bandwidth Measurement of Complex Permittivity of Liquids using Coplanar Lines,” IEEE Transactions on Instrumentation and Measurement, Vol.50, pp.905 (2001). [4.5] K. Grenier, D. Dubuc, P.-E. Poleni, M. Kumemura, H. Toshiyoshi, T. Fujii, and H. Fujita, “Integrated Broadband Microwave and Microfluidic Sensor Dedicated to Bioengineering,” IEEE Transactions on Microwave Theory and Techniques, Vol.57, pp.3246 (2009). [4.6] R.-Y. Yang, Y.-K. Su, M.-H. Weng, C.-Y. Hung, and H.-W. Wu, “Characteristics of coplanar waveguide on lithium niobate crystals as a microwave substrate,” Journal of Applied Physics, Vol.101, 014101 (2007). [4.7] D. M. Pozar, Microwave Engineering Forth Edition, John Wiley & Sons, Inc, pp.178 (2011). [4.8] M. Tanaka and M. Sato, “Microwave heating of water, ice, and saline solution: Molecular dynamics study,” Journal of Chemical Physics, Vol.126, 034509 (2007). [4.9] T. Meissner and F. J. Wentz, “The Complex Dielectric Constant of Pure and Sea Water From Microwave Satellite Observations,” IEEE Transactions on Geoscience and Remote Sensing, Vol.42, pp.1836 (2004). [4.10] L. A. Klein and C. T. Swift, “An Improved Model for- the Dielectric Constant of Sea Water at Microwave. Frequencies,” IEEE Transactions on Antennas and Propagation, Vol.25, pp.104 (1977). [4.11] K. Z. Jadoon, F. Andre, J. V. D. Kruk, E. Slob, H. Vereecken, and S. Lambot, “Ground-Penetrating Radar Characterization of Water as a Function of Frequency, Salinity and Temperature,” IEEE Advanced Ground Penetrating Radar (IWAGPR), 2011 6th International Workshop on, pp.1 (2011). [4.12] W. J. Ellison, “Permittivity of Pure Water, at Standard Atmospheric Pressure, over the Frequency Range 0–25 THz and the Temperature Range 0–100°C,” Journal of Physical Chemistry, Vol.36, pp.1 (2007). [4.13] R. Buchner, J. Barthel, and J. Stauber, “The dielectric relaxation of water between 0°C and 35°C,” Chemical Physics Letters, Vol.306, pp.57 (1999). [4.14] O. R. Per and W.-R. Birgitta, “Retro-modelling of a dual resonant applicator and accurate dielectric properties of liquid water from −20°C to +100°C,” Measurement Science and Technology, Vol.18, pp.959 (2007). [4.15] C. Gabriel and A. Peyman, “Dielectric measurement: error analysis and assessment of uncertainty,” Physics in Medicine and Biology, Vol.51, pp.6033 (2006). [4.16] J.-M. Tsai, H.-C. Wang, J.-H. Leu, A. H.-J. Wang, Y. Z., P. J. Walker, G.-H. Kou, and C.-F. Lo, “Identification of the Nucleocapsid, Tegument, and Envelope Proteins of the Shrimp White Spot Syndrome Virus Virion,” Journal of Virology, Vol.80, pp.3021 (2006). [4.17]C. F. Lo, C. H. Ho, S. E. Peng, C. H. Chen, H. E. Hsu, Y. L. Chiu, C. F. Chang, K. F. Liu, M. S. Su, C. H. Wang, and G. H. Kou, “White spot syndrome baculovirus (WSBV) detected in cultured and captured shrimp, crabs and other arthropods,” Diseases of Aquatic Organisms, Vol.27, pp.215 (1996). [4.18] M. C. W. van Hulten, J. Witteveldt, S. Peters, N. Kloosterboer, R. Tarchini, M. Fiers, H. Sandbrink, R. K. Lankhorst, and J. M. Vlak, “The White Spot Syndrome Virus DNA Genome Sequence,” Journal of Virology, Vol.286, pp.7 (2001). [4.19] J.-M. Tsai, H.-C. Wang, J.-H. Leu, H.-H. Hsiao, A. H.-J. Wang, G.-H. Kou, and C.-F. Lo, “Genomic and Proteomic Analysis of Thirty-Nine Structural Proteins of Shrimp White Spot Syndrome Virus,” Journal of Virology, Vol.78, pp.11360 (2004). [4.20] C. B. N. Jr, L. M. Tapay, P. C. Loh, “Characterization of a non-occluded baculovirus-like agent pathogenic to penaeid shrimp,” Diseases of aquatic organisms, Vol.33, pp.221 (1998). [4.21] “WHITE SPOT DISEASE,” Manual of Diagnostic Tests for Aquatic Animals 2012, Chapter 2.2.6, pp.177 (2012).
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/56631	-
dc.description.abstract	病毒是一種廣為人知的微生物，它只能在宿主的細胞系統進行自我複製，無法獨立生長與複製。根據病毒的幾何形狀，大多數病毒可以簡單分為球狀病毒和桿狀病毒兩類。一般而言，不少種球狀病毒會對人體有感染性，然而桿狀病毒幾乎不會，大多數桿狀病毒主要會感染無脊椎動物(如:昆蟲和蝦子)、植物或是細菌。近期有人開始研究病毒的微波共振吸收特性，其原理是透過微波和侷限的有聲振動進行偶極性耦合進而發生共振吸收。如果將一個病毒粒視為一個自由且同質性的奈米粒子，而此病毒的微波共振吸收頻率會與其幾何形狀、質量密度以及彈性特性有關。目前為止，只有球狀病毒的微波共振吸收已被發現，且其共振頻率和偶極模態的頻率吻合，而桿狀病毒還未被發現具有微波共振吸收的特性。在此論文中，我們是將一個桿狀病毒看作為自由同質性的奈米柱，而此奈米柱具有和桿狀病毒相同的大小和物理特性，再來根據不同電荷分布情況，分析每一個模態在振動過程中偶極矩的變化量，最後得出桿狀病毒會在哪些振動模態有比較強的微波共振吸收。為了讓理論模型更完整以及更吻合各種桿狀病毒，我們除了建立基本的圓柱模型之外，也建立了膠囊模型，再利用有限元素分析法來求出它們的振動模態。此外，我們主要用共平面波導結合微流道和網路分析儀作為量測病毒的實驗系統，並且用此系統成功地量測出蝦白點病毒的微波共振吸收，其共振吸收頻率也落在理論的分析結果範圍內。從我們的研究分析可以推測桿狀病毒的微波共振吸收會發生在哪些振動模態，此外我們也建立了一個量測病毒微波共振吸收特性的實驗系統，這些研究對於迅速又準確的桿狀病毒偵測發展是重要的一步，同時也可以應用於分析桿狀病毒的物理特性。	zh_TW
dc.description.abstract	Virus is a well-known microorganism and the infectious agent that replicates only in the living cells of other organisms. Based on the geometric structure of viruses, most viruses can be simply classified as spherical (or icosahedral) viruses and rod-shaped viruses. In general, most spherical viruses are infectious for human being while rod-shaped viruses are almost not. Most rod-shaped viruses can infect invertebrates (such as insects and shrimps), plants or bacteria. Recently, the microwave resonant absorption (MRA) of viruses has been researched. This MRA mechanism is through dipolar coupling to confined acoustic vibrations. By treating one virion as a free homogeneous nanoparticle, the unique geometrical and mechanical properties of viruses can be reflected by the MRA frequencies. So far, only the MRA of spherical viruses have been discovered, and the MRA frequencies agree well with that of dipolar vibration modes. However, the MRA characteristic of rod-shaped viruses hasn’t been found. In this thesis, we treat a rod-shaped virus as a free homogenous nanorod with the rod-shaped virus’s geometrical and elastic properties and identify the vibration modes of a nanorod which can cause the stronger MRA in different charge distribution situations through analyzing the dipolar modulations of each vibration mode. We analyzed not only the cylinder model but also the capsule model, which let our theoretical model more complete and match the rod-shape virus better. The vibration modes are simulated by finite element method in both models. Moreover, we successfully discover the MRA of white spot syndrome virus (WSSV), which is one of rod-shaped viruses, by our MRA experiment system. This system mainly utilizes a coplanar waveguide combined with a microfluidic channel and a vector network analyzer. We also find that the MRA frequencies of WSSV closely agree with our analysis results. From our study results, we propose a theory to know that the MRA of rod-shaped viruses should happen in which vibration modes and also develop an MRA system to measure the viruses. Our study is an important step to achieve rapid and sensitive detection of rod-shaped viruses and a method to know the physical properties of rod-shaped viruses.	en
dc.description.provenance	Made available in DSpace on 2021-06-16T05:38:53Z (GMT). No. of bitstreams: 1 ntu-103-R01941007-1.pdf: 9036316 bytes, checksum: f1e1890f119fe6fa5fc966b59db01451 (MD5) Previous issue date: 2014	en
dc.description.tableofcontents	CONTENTS 口試委員會審定書 I 致謝 II 摘要 IV ABSTRACT V CONTENTS VII LIST OF FIGURES X LIST OF TABLES XV Chapter 1 Introduction 1 Reference 4 Chapter 2 Vibration modes of a spherical virus 6 2.1 The introduction of vibration modes of a spherical particle 6 2.2 Microwave resonant absorption (MRA) of spherical virus through dipolar coupling with confined acoustic vibrations 10 Reference 14 Chapter 3 Dipolar modes of rod-shaped viruses 17 3.1 Vibrations of a solid, isotropic and elastic cylinder 17 3.2 The simulation for vibrations of a homogenous circular cylinder 27 3.3 The modes of the cylinder with high dipolar modulation in specific cases 35 3.3.1 Vibration modes in uniform and symmetric charge distribution case 36 3.3.2 Vibration modes in asymmetric charge distribution case 40 3.3.3 Summary the results for two main cases 43 3.4 The vibration modes of the capsule model and frequency analysis of white spot syndrome virus (WSSV) 63 3.4.1 Vibration modes in uniform and symmetric charge distribution case 66 3.4.2 The frequency analysis of white spot syndrome virus (WSSV) 75 Reference 78 Chapter 4 Measurement of microwave resonant absorption for rod-shape viruses 82 4.1 Experiment setup 82 4.2 Calibration methods 89 4.3 Experimental result and discussion 96 4.3.1 White spot syndrome virus (WSSV) solution preparation 96 4.3.2 The microwave resonant absorption spectra of WSSV and conclusion 99 Reference 104 Chapter 5 Summary 108 Appendix A Fabrication Process of high frequency up to 65GHz broadband coplanar waveguide 110 Appendix B Commercial dielectric materials (Rogers Corporation, RO4003C) 112 Appendix C Copyright Permissions of Figures 113
dc.language.iso	en
dc.subject	微波共振吸收	zh_TW
dc.subject	桿狀病毒	zh_TW
dc.subject	偶極模態	zh_TW
dc.subject	rod shaped virus	en
dc.subject	microwave resonant absorption	en
dc.subject	dipolar vibration mode	en
dc.title	桿狀病毒的偶極模態分析與其微波共振吸收量測	zh_TW
dc.title	The dipolar mode analysis and microwave resonant absorption measurements of rod-shaped viruses	en
dc.type	Thesis
dc.date.schoolyear	102-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	吳政忠,劉子銘
dc.subject.keyword	桿狀病毒,微波共振吸收,偶極模態,	zh_TW
dc.subject.keyword	rod shaped virus,microwave resonant absorption,dipolar vibration mode,	en
dc.relation.page	114
dc.rights.note	有償授權
dc.date.accepted	2014-08-12
dc.contributor.author-college	電機資訊學院	zh_TW
dc.contributor.author-dept	光電工程學研究所	zh_TW
顯示於系所單位：	光電工程學研究所

文件中的檔案：

檔案	大小	格式
ntu-103-1.pdf 未授權公開取用	8.82 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。