基於單原子電子源之低能量同調電子繞射成像術

Chun-Yueh Lin; 林君岳

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/51163

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	張嘉升(Chia-Seng Chang)
dc.contributor.author	Chun-Yueh Lin	en
dc.contributor.author	林君岳	zh_TW
dc.date.accessioned	2021-06-15T13:26:28Z	-
dc.date.available	2019-04-15
dc.date.copyright	2016-04-15
dc.date.issued	2016
dc.date.submitted	2016-03-23
dc.identifier.citation	1. E. Ruska, M. Knoll, “Die magnetische Sammelspule fuer schnelle Elektronenstrahlen”, Z. Techn. Physik 12 389 (1931). 2. O. Scherzer, “Über einige Fehler von Elektronenlinsen” Z. Phys. 101 593 (1936). 3. M. Haider, S. Uhlemann, E. Schwan, H. Rose, B. Kabius, K. Urban, “Electron microscopy image enhanced”, Nature 392 768 (1998). 4. O.L. Krivanek, N. Dellby, A.J. Spence, R.A. Camps, L.M. Brown, “Aberration correction in the STEM”, Inst. Phys. Conf. Ser. 153 35 (1997). 5. C. Kisielowski, B. Freitag, M. Bischoff, H. van Lin, S. Lazar, G. Knippels, P. Tiemeijer, M. van der Stam, S. von Harrach, M. Stekelenburg, M. Haider, S. Uhlemann, H. Müller, P. Hartel, B. Kabius, D. Miller, I. Petrov, E.A. Olson, T. Donchev, E.A. Kenik, A.R. Lupini, J. Bentley, S.J. Pennycook, I.M. Anderson, A.M. Minor, A.K. Schmid, T. Duden, V. Radmilovic, Q.M. Ramasse, M. Watanabe, R. Erni, E.A. Stach, P. Denes, U. Dahmen, “Detection of Single Atoms and Buried Defects in Three Dimensions by Aberration-Corrected Electron Microscope with 0.5-Å Information Limit”, Microsc. Microanal. 14 469 (2008). 6. R.F. Egerton, “Choice of operating voltage for a transmission electron microscope”, Ultramicroscopy 145 85 (2014). 7. T. Sasaki, H. Sawada, F. Hosokawa, Y. Kohno, T. Tomita, T. Kaneyama, Y. Kondo, K. Kimoto, Y. Sato, K. Suenaga, “Performance of low-voltage STEM/TEM with delta corrector and cold field emission gun”, J. Electr. Microsc. 59 s7 (2010) 8. O.L. Krivanek, N. Dellby, M.F. Murfitt, M.F. Chisholm, T.J. Pennycook, K. Suenaga, V. Nicolosi, “Gentle STEM: ADF imaging and EELS at low primary energies”, Ultramicrscopy 110 935 (2010). 9. U. Kaiser, J. Biskupek, J.C. Meyer, J. Leschner, L. Lechner, H.H. Rose, M. Stoger-Pollach, A.N. Khlobystov, P. Hartel, H. Müller, M. Haider, S. Eyhusen, G. Benner, “Transmission electron microscopy at 20 kV for imaging and spectroscopy”, Ultramicroscopy 111 1239 (2011). 10. D.C. Bell, N. Erdman, “Low Voltage Electron Microscopy: Principles and Applications”, (Wiley, New Jersey 2013). 11. O. Scherzer, “Die Strahlenschädigung der Objekte als Grenze für die hochauflösende Elektronenmikroskopie”, Ber. Bunsenges. Phys. Chem. 74 1154 (1970). 12. R.M. Glaeser, K.A. Taylor, “Radiation damage relative to transmission electron microscopy of biological specimens at low temperature: a review”, J. Microscopy 112 127 (1978). 13. H.H. Rose, “Future trends in aberration-corrected electron microscopy”, Phil. Trans. R. Soc. A 367 3809 (2009). 14. U. Kaiser, J. Meyer, J. Biskupek, J. Leschner, A.N. Khlobystov, H. Müller, P. Hartel , M. Haider, S. Eyhusen, G. Benner, “High resolution 20kV transmission electron microscopy of nanosystems – first results towards sub Ångstrom low voltage EM (SALVE-Microscopy)”, Microsc. Microanal. 16 (S2) 1702 (2010). 15. T. Sasaki, H. Sawada, F. Hosokawa, Y. Shimizu, T. Nakamichi, S. Yuasa, M. Kawazoe, T. Kaneyama, Y. Kondo, K. Kimot, K. Suenaga, “Performance and application of chromatic/spherical aberration-corrected 30kV transmission electron microscope”, Microsc. Microanal. 17 (S2) 1530 (2011). 16. N. Dellby, N.J. Bacon N J, P. Hrncirik, M.F. Murfitt, G.S. Skone, Z.S. Szilagyi, O.L. Krivanek, “Dedicated STEM for 200 to 40 keV operation”, Eur. Phys. J. Appl. Phys. 54 33505 (2011). 17. T. Sasaki, H. Sawada, F. Hosokawa, Y. Sato, K. Suenaga, “Aberration-corrected STEM/TEM imaging at 15 kV”, Ultramicroscopy 145 50 (2014). 18. J.C. Meyer, F. Eder, S. Kurasch, V. Skakalova, J. Kotakoski, H.J Park, S. Roth, A. Chuvilin, S. Eyhusen, G. Benner, A.V. Krasheninnikov, U. Kaiser, “Accurate measurement of electron beam induced displacement cross sections for single-layer garphene”, Phys. Rev. Lett. 108 196102 (2012). 19. K. Suenaga, Y. Iizumi, T. Okazaki, “Single atom spectroscopy with reduced delocalization effect using a 30 kV-STEM”, Eur. Phys. J. Appl. Phys. 54 33508 (2011). 20. N. Jiang, J.C.H. Spence, “ On the dose-rate threshold of beam damage in TEM”, Ultramicroscopy 113 77 (2012). 21. R.F. Egerton, P. Li, M. Malac, “Radiation damage in the TEM and SEM”, Micron 35 399 (2004). 22. L.F. Drummy, J. Yang, D.C. Martin, “Low-voltage electron microscopy of polymer and organic molecular thin films”, Ultramicroscopy 99 247 (2004). 23. J.R. Fienup, “Reconstruction of an object from the modulus of its Fourier transform”, Opt. Lett. 3 27 (1978). 24. J.R. Fienup, “Phase retrieval algorithms: a comparison”, Appl. Opt. 21 2758 (1982). 25. J.M. Miao, D. Sayre, H.N. Chapman, “Phase retrieval from the magnitude of the Fourier transforms of nonperiodic objects“, J. Opt. Soc. Am. A 15 1662 (1998). 26. J. Miao, J. Kriz, D. Sayre, “The oversampling phasing method”, Acta Cryst. D 56 1312 (2000). 27. H.M.L. Faulkner, J.M. Rodenburg, “Movable aperture lensless transmission microscopy: a novel phase retrieval algorithm”, Phys. Rev. Lett. 93 023903 (2004). 28. A.M. Maiden, J.M. Rodenburg, “An improved ptychographical phase retrieval algorithm for diffractive imaging“, Ultramicroscopy 109 1256 (2009). 29. J. Miao, P. Charalambous, J. Kriz, D. Sayre, “Extending the methodology of X-ray crystallography to allow imaging of micrometer-sized non-crystalline specimens“, Nature 400 342 (1999). 30. U. Weierstall, Q. Chen, J.C.H. Spence, M.R. Howells, M. Isaacson, R.R. Panepucci, “Image reconstruction from electron and X-ray diffraction patterns using iterative algorithms: experiment and simulation“, Ultramicroscopy 90 171 (2002). 31. J.M. Zuo, I. Vartanyants, M. Gao, R. Zhang, L.A. Nagahara, “Atomic resolution imaging of a carbon nanotube from diffraction intensities“, Science 300 1419 (2003). 32. S. Morishita, J. Yamasaki, K. Nakamura, T. Kato, N. Tanaka, “Diffractive imaging of the dumbbell structure in silicon by spherical-aberration corrected electron diffraction”, Appl. Phys. Lett. 93 183103 (2008). 33. W.J. Huang, J.M. Zuo, B. Jiang, K.W. Kwon, M. Shim, “sub-ångström-resolution diffractive imaging of single nanocrystals”, Nat. Phys. 5 129 (2009). 34. L.D. Caro, E. Carlino, G. Caputo, P.D. Cozzoli, C. Giannin, “Electron diffractive imaging of oxygen atoms in nanocrystals at sub- sub-ångström resolution”, Nat. Nanotechnol. 5 360 (2010). 35. O. Kamimura, Y. Maehara, T. Dobashi, K. Kobayashi, R. Kitaura, H. Shinohara, H. Shioya, K. Gohara, “Low voltage electron diffractive imaging of atomic structure in single-wall carbon nanotubes”, Appl. Phys. Lett. 98 174103 (2011) 36. O. Kamimura, T. Dobashi, K. Kawahara, T. Abe, K. Gohar, “10-kV diffractive imaging using newly developed electron diffraction microscope”, Ultramicroscopy 110 130 (2010). 37. M.J. Humphry, B. Kraus, A.C. Hurst, A.M. Maiden, J.M. Rodenburg, “Ptychographic electron microscopy using high-angle dark-field scattering for sub-nanometre resolution imaging”, Nature Commu. 3 730 (2012). 38. L.N. Longchamp, T. Latychevskaia, C. Escher, H.W. Fink, “Graphene unit cell imaging by holographic coherent diffraction“, Phys. Rev. Lett. 110 255501 (2013). 39. P. C. Kuo, I. H. Chen, C. T. Chen, K. P. Lee, C. W. Chen, C. C. Lin, S. W. Y. Chiu, Y. F. Hsieh, Y. L. Wang, and J. Shiue, 'On-Chip Thin Film Zernike Phase Plate for In-Focus Transmission Electron Microscopy Imaging of Organic Materials', ACS Nano 7 465 (2013). 40. H. Liche, M. Lehmann, “Electron holography – basics and applications”, Rep. Prog. Phys. 71 016102 (2008). 41. Zangwill ZA, “Physics at Surface”, (Cambridge University, Cambridge 1998). 42. J.C.H. Spence, U. Weierstall, M. Howells, “Coherence and sampling requirements for diffractive imaging“, Ultramicroscopy 101 149 (2004). 43. T.Y. Fu, L.C. Cheng, C.H. Nien, T.T. Tsong, “Method of creating a Pd-covered single-atom sharp W pyramidal tip: mechanism and energetics of its formation“, Phys. Rev. B 64 113401 (2001). 44. H.S. Kuo, I.S. Hwang, T.Y. Fu, J.Y. Wu, C.C. Chang, T.T. Tsong, “Preparation and characterization of single-atom tips“, Nano Lett. 4 2379 (2004). 45. H.S. Kuo, I.S. Hwang, T.Y. Fu, Y.C. Lin, C.C. Chang, T.T. Tsong, “Noble Metal/W(111) Single-Atom Tips and Their Field Electron and Ion Emission Characteristics“, Jpn. J. Appl. Phys. 45 8972 (2006). 46. C.C. Chang, H.S. Kuo, I.S. Hwang, T.T. Tsong, “A fully coherent electron beam from a noble-metal covered W(111) single-atom emitter“, Nanotechnology 20 115401 (2009). 47. I.S. Hwang, H.S. Kuo, C.C. Chang, T.T. Tsong, “Noble-metal covered W(111) single-atom electron sources”, J. Electrochem. Soc. 157 7 (2010). 48. G. Pozzi, “Theoretical considerations on the spatial coherence in field emission electron microscopes”, Optik 77 69 (1987). 49. D.B. Williams, C.B. Carter, “Transmission Electron Microscopy”, (Springer, New York 2009). 50. R.W. Gerchberg, W.O. Saxton, “A practical algorithm for the determination of the phase from image and diffraction plane pictures”, Optik 35 237 (1972). 51. R.H.T. Bates, “Fourier phase problems are uniquely soluble in more than one dimension. I: underlying theory”, Optik 61 247 (1982). 52. J.R. Fienup, “Itertative method applied to image reconstruction and to computer - generated holograms”, Opt. Eng. 19 297 (1980). 53. M.R. Scheinfein, W. Qian, J.C.H. Spence, “Aberrations of emission cathodes: Nanometer diameter field-emission electron sources”, J. App. Phys. 73 2057 (1993). 54. C. Oshima, E. Rokuta, T. Itagaki, T. Ishikawa, B. Cho, H.S. Kuo, I.S. Hwang, T.T. Tsong, “Demountable single-atom electron source”, e-J. Surf. Sci. Nanotech. 3 412 (2005). 55. K.J. Song, R.A. Demmin, C. Dong, E. Garfunkel, T.E. Madey, “Faceting induced by an ultrathin metal film: Pt on W(111)”, Surf. Sci. Lett. 227 L79 (1990). 56. K.J. Song, C.Z. Dong, T.E. Madey, “Faceting of W(111) induced by ultrathin Pd films”, Langmuir 7 3019 (1991). 57. T.E. Madey, C.H. Nien, K. Pelhos, J.J. Kolodziej, I.M. Abdelrehim, H.S. Tao, “Faceting induced by ultrathin metal films: structure, electronic properties and reactivity”, Surf. Sci. 438 191 (1999). 58. S.P. Chen, “Theoretical studies of ultrathin film-induced faceting on W(111) surfaces”, Surf. Sci. Lett. 274 L619 (1992). 59. J.G. Che, C.T. Chan, C.H. Kuo, T.C. Leung, “Faceting Induced by Ultrathin Metal Films: A First Principles Study”, Phys. Rev. Lett. 79 4230 (1997). 60. T. Ishikawa, T. Urata, B. Cho, E. Rokuta, C. Oshima, “Highly efficient electron gun with a single-atom electron source”, Appl. Phys. Lett. 90 143120 (2007). 61. H.W. Fink, W. Stocker, H. Schmid, “Holography with low-energy electrons”, Phys. Rev. Lett. 65 1204 (1990). 62. V.T. Binh, V. Semet, N. Garcia, “Low energy electorn diffraction by nano-objects in projection microscopy without magnetic shielding”, Appl. Phys. Lett. 65 2493 (1994). 63. D.W.O. Heddle, “Electrostatic lens systems”, (IOP, London 2000). 64. G.C. King, “Atomic, Molecular, and Optical Physics: Charged Particles, edited by F.B. Dunning, R.G. Hulet”, (Academic, San Diego 1995), Vol. 29A, pp. 189-207. 65. J.H. Moore, C.C. Davis, M.A. Coplan, “Building Scientific Apparatus”, (Cambridge, New York 2009). 66. E. Harting, F.H. Read, “Electrostatic lenses”, (Elsevier, Amsterdam 1976). 67. M. Szilagyi, J. Szep, “Optimum design of electrostatic lenses”, J. Vac. Sci. Technol. B 6 953 (1988). 68. A.V. Crewe, D.N. Eggenberger, J. Wall, L.M. Welter, “Electron gun using a field emission source”, Rev. Sci. Instrum. 39 576 (1968). 69. J.W. Butler, “Digital computer techniques in electron microscopy”, 6th Intern. Congr. Electron Microscopy (Kyoto), pp. 191 (1966). 70. E. Munro, “Design of electrostatic lenses for field-emission electron guns”, Electron Microscopy 1972, (Institute of Physics, London 1972), pp. 22. 71. K. Kuroda, T. Suzuki, “Analysis of accelerating lens system in field-emission scanning electron microscope”, J. Appl. Phys. 45 1436 (1974). 72. R Browning, P.J. Bassett, M.M.El Gomati, M. Prutton, “A digital scanning Auger electron microscope incorporating a concentric hemispherical analyser”, Proc. R. Soc. Lond. A. 357 213 (1977). 73. M. Prutton, R. Browning, M.M.El Gomati, D. Peacock, “Scanning Auger electron microscopy with high spatial or high energy resolution”, Vacuum 32 351 (1982). 74. M.M.E. Gomati, M. Prutton, R. Browning, “An all-electrostatic small beam diameter, high probe current field emission electron probe”, J. Phys. E: Sci. Instrum. 18 32 (1985). 75. R.E. Imhof, F.H. Read, “A three-aperture electron optical lens for producing an image of variable energy but fixed position”, J. Phys. E: Sci. Instrum. 1 859 (1968). 76. F.H. Read, “Asymmetric electrostatic lenses of three apertures”, J. Phys. E: Sci. Instrum. 3 127 (1970). 77. A. Adams, F.H. Read, “Electrostatic cylinder lenses III: three element asymmetric voltage lenses”, J. Phys. E: Sci. Instrum. 5 156 (1972). 78. D.W.O. Heddle, “The design of three-element electrostatic electron lenses”, J. Phys. E: Sci. Instrum. 2 1046 (1969). 79. D.W.O. Heddle, M.V. Kurepa, “The focal properties of three-element electrostatic electron lenses”, J. Phys. E: Sci. Instrum. 3 552 (1970). 80. G.H.N. Riddle, “Electrostatic einzel lenses with reduced spherical aberration for use in field-emission guns”, J. Vac. Sci. Technol. 15 857 (1978). 81. J. Orloff, L.W. Swanson, “An asymmetric electrostatic lens for field-emission microprobe applications”, J. Appl. Phys. 50 2494 (1979). 82. E.T. Hwu, H.S. Liao, I.S. Hwang, “Friction-driven actuator”, U.S. Patent No. 8,912,707 B2 (16 December 2014). 83. W.T. Chang, I.S. Hwang, M.T. Chang, C.Y. Lin, W.H. Hsu, J.L. Hou, “Method of electrochemical etching of tungsten tips with controllable profiles”, Rev. Sci. Instrum. 83 083704 (2012). 84. W.H. Lin, T.H. Chen, J.K. Chang, J.I. Taur, Y.Y. Lo, W.L. Lee, C.S. Chang, W.B. Su, C.I. Wu, “A direct and polymer-free method for transferring graphene grown by chemical vapor deposition to any substrate”, ASC Nano 8 1784 (2014). 85. H. Kiesel, A. Renz, F.Hasselbach, “Observation of Hanbury Brown-Twiss anticorrelations for free electrons”, Nature 418 392394 (2002). 86. http://www.simion.com (SIMION) 87. O. Sise, M. Ulu, M. Dogan, “Characterization and modeling of multi-element electrostatic lens systems”, Radiat. Phys. Chem. 76 593 (2007). 88. P. Grivet, “Electron optics”, (Pergamon, Oxford 1972) 89. http://www.electronoptics.com (CPO2D/CPO3D) 90. F.H. Read, N.J. Bowring, “The CPO programs and the BEM for charged particle optics”, Nucl. Instr. Meth. A 645 273 (2011). 91. http://www.lencova.com (EOD) 92. http://www.mebs.co.uk (MEBS) 93. http://www.operafea.com (OPERA) 94. E. Rokuta, H.S. Kuo, T. Itagaki, K. Nomura, T. Ishikawa, B.L. Cho, I.S. Hwang, T.T. Tsong, C. Oshima, “Field emission spectra of single-atom tips with thermodynamically stable structures”, Surf. Sci. 602 2508 (2008). 95. T. Ohnishi, S. Hosaka, H. Tamura, T. Ishitani, T. Noda, “A new resistor network for an electrostatic octupole deflector comnined with a stigmator”, Rev. Sci. Instrum. 62 240 (1991). 96. I.S. Hwang, C.C. Chang, C.H. Lu, S.C. Liu, Y.C. Chang, T.K. Lee, H.T. Jeng, H.S. Kuo, C.Y. Lin, C.S. Chang, T.T. Tsong, “Investigation of single-walled carbon nanotubes with a low-energy electron point projection microscope”, New J. Phys. 15 043015 (2013). 97. A. Tonomura, “Applications of electron holography”, Rev. Mod. Phys. 59 637 (1987). 98. A. Tonomura, “Present and future of electron holography”, J. Electron Microsc. 38 S43 (1989). 99. A. Tonomura, “Electron holography, a new view of the microscopic”, Phys. Today 22 22 (1990). 100. 李宗隆, “Structure of single-walled carbon nanotubes”, 奈米通訊，第十二卷第三期
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/51163	-
dc.description.abstract	在這項工作中，我們建造了一個使用單原子電子源的低能量同調電子繞射成像顯微鏡。它包括一個單原子場發射源，一組三極式的靜電透鏡、結合奈米尺度步進器的樣品台，和一個可前後移動之延遲線偵測器，使用此偵測器可以在樣品後方不同距離記錄繞射圖案。此顯微鏡的設計非常適合對3奈米厚度以下的極薄樣品進行成像。我們分析了其中用於聚焦電子束的非對稱三極式靜電透鏡，並以2千電子伏特的電子能量在樣品平面取得直徑為87奈米的聚焦束斑。利用此儀器，我們成功地記錄到對應0.62埃解析度的石墨烯樣品高角度繞射圖案，我們同時進行了數值模擬，並以此模擬結果與實驗結果進行比對。這項工作展示了操作電壓在1-10千伏時，同調電子繞射成像術在超薄二維材料、生物分子和奈米材料等方面的潛力。該儀器的最終目標是取得這些材料的高對比、原子解析度影像。	zh_TW
dc.description.abstract	In this work, a transmission-type, low-kilovolt coherent electron diffractive imaging instrument was constructed. It comprised a single-atom field emitter, a triple-element electrostatic lens, a sample holder, and a retractable delay line detector to record the diffraction patterns at different positions behind the sample. It was designed to image materials thinner than 3 nm. We analyzed the asymmetric triple-element electrostatic lens for focusing the electron beams and achieved a focused beam spot of 87 nm on the sample plane at the electron energy of 2 kV. High-angle coherent diffraction patterns of a suspended graphene sample corresponding to (0.62 Å)-1 were recorded. The simulated results were calculated to compare with the experimental results. This work demonstrated the potential of coherent diffractive imaging of thin 2D materials, biological molecules, and nano-objects at voltage between 1-10 kV. The ultimate goal of this instrument is to achieve atomic resolution of these materials with high contrast and little radiation damage.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T13:26:28Z (GMT). No. of bitstreams: 1 ntu-105-D97222013-1.pdf: 4232426 bytes, checksum: 6b54a349c7956becafce1e08ca492230 (MD5) Previous issue date: 2016	en
dc.description.tableofcontents	口試委員會審定書 ……………………………………………………I Acknowlegdements ………………………………………………………II 中文摘要 ……………………………………………………………III Abstract …………………………………………………………………IV Table of Contents …………………………………………………………V Figure Captions…………………………………………………………VIII Table Captions…………………………………………………………XIV Chapter 1 .........................................................................................................1 Introduction .....................................................................................................1 1.1 Background of the research ................................................................1 1.2 Outline of this dissertation ..................................................................5 Chapter 2 .........................................................................................................7 Literature Review............................................................................................7 2.1 Coherent diffractive imaging ..............................................................7 2.1.1 Phase retrieval algorithms in CDI................................................9 2.1.1.1 Error-reduction algorithm (ER)................................................ 10 2.1.1.2 Input-output algorithm............................................................... 12 2.1.2 Requirement in CDI.................................................................... 15 2.2 Noble-metal covered W(111) SAT field emitters ........................... 17 2.2.1 Noble-metal covered W(111) SATs ........................................... 18 2.2.2 Field emission properties of noble-metal covered W(111) SATs....................................................................................................... 19 2.2.3 Fully coherent electron beams from noble-metal covered W(111) SAT emitters ........................................................................... 22 2.3 Electrostatic lenses ............................................................................ 24 2.3.1 Aberrations of electrostatic lenses............................................. 25 2.3.2 Multi-element electrostatic lens ................................................. 28 Chapter 3 ...................................................................................................... 34 Experimental Details .................................................................................... 34 3.1 Instrumentation................................................................................. 34 3.1.1 UHV-chamber ............................................................................. 35 3.1.2 Multi-axis piezo-nanopositioners............................................... 36 3.1.3 Detector ........................................................................................ 36 3.2 SAT preparation................................................................................ 37 3.3 Sample preparation........................................................................... 40 Chapter 4 ...................................................................................................... 43 Electrostatic Gun Lenses for SAT Emitters ................................................. 43 4.1 Features and strategy for SAT electron sources ............................ 43 4.2 Two-element lens for SAT electron sources ................................... 46 4.3 Three-element lens for SAT electron sources................................. 49 Chapter 5 ...................................................................................................... 54 Optimized Electrostatic Lens for Low-kilovolt CDI ................................... 54 5.1 Computer simulation for charged particle optics .......................... 54 5.1.1 SIMION........................................................................................ 56 5.1.2 CPO2D/CPO3D........................................................................... 57 5.2 Modeling of three-element electrostatic lens .................................. 59 5.3 Implementation of the optimized three-element electrostatic lens64 Chapter 6 ...................................................................................................... 66 Low-kilovolt Coherent Electron Diffractive Imaging Instrument Based on a Single-atom Electron Source........................................................................ 66 6.1 Analyses of the three-element electrostatic lens............................. 67 6.2 Coherent diffraction patterns of a suspended graphene............... 69 6.3 Discussion........................................................................................... 73 Chapter 7 ...................................................................................................... 75 Simulation for Coherent Diffraction Patterns of a Suspended Monolayer Graphene....................................................................................................... 75 7.1 Theoretical principle......................................................................... 75 7.2 Simulate diffraction patterns of a suspended graphene................ 79 Chapter 8 ...................................................................................................... 83 Conclusions and Future Works .................................................................... 83 References .................................................................................................... 85
dc.language.iso	en
dc.subject	單原子針	zh_TW
dc.subject	靜電透鏡	zh_TW
dc.subject	同調繞射成像術	zh_TW
dc.subject	低能量電子束	zh_TW
dc.subject	電子顯微鏡	zh_TW
dc.subject	單原子針	zh_TW
dc.subject	靜電透鏡	zh_TW
dc.subject	同調繞射成像術	zh_TW
dc.subject	電子顯微鏡	zh_TW
dc.subject	低能量電子束	zh_TW
dc.subject	low-energy electron beams	en
dc.subject	coherent diffractive imaging	en
dc.subject	electrostatic lens	en
dc.subject	SIMION	en
dc.subject	single-atom electron sources	en
dc.subject	electron microscopy	en
dc.subject	CPO	en
dc.subject	coherent diffractive imaging	en
dc.subject	electrostatic lens	en
dc.subject	SIMION	en
dc.subject	single-atom electron sources	en
dc.subject	electron microscopy	en
dc.subject	CPO	en
dc.subject	low-energy electron beams	en
dc.title	基於單原子電子源之低能量同調電子繞射成像術	zh_TW
dc.title	Low-kilovolt Coherent Electron Diffractive Imaging Based on a Single-Atom Electron Source	en
dc.type	Thesis
dc.date.schoolyear	104-2
dc.description.degree	博士
dc.contributor.coadvisor	黃英碩(Ing-Shouh Hwang)
dc.contributor.oralexamcommittee	朱明文(Ming-Wen Chu),趙良君(Liang-Chiun Chao),章為皓(Wei-Hau Chang),陳健群(Chien-Chun Chen)
dc.subject.keyword	同調繞射成像術,靜電透鏡,單原子針,電子顯微鏡,低能量電子束,	zh_TW
dc.subject.keyword	coherent diffractive imaging,electrostatic lens,SIMION,single-atom electron sources,electron microscopy,CPO,low-energy electron beams,	en
dc.relation.page	92
dc.identifier.doi	10.6342/NTU201600131
dc.rights.note	有償授權
dc.date.accepted	2016-03-23
dc.contributor.author-college	理學院	zh_TW
dc.contributor.author-dept	物理學研究所	zh_TW
顯示於系所單位：	物理學系

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