Name:



Publications

Invited Book Chapters and Reviews

1. R.M. Taylor II, D. Borland, F. P. Brooks Jr., M. Falvo, M. Guthold, T. Hudson, K. Jeffay, G. Jones, D. Marshburn, S. J. Papadakis, L.-C. Qin, A. Seeger, F. D. Smith, D. H. Sonnenwald, R. Superfine, S. Washburn, C. Weigle, M. C. Whitton, P. Williams, L. Vicci and W. Robinett. “Visualization and Natural Control Systems for Microscopy.” In: Visualization Handbook; Edited by C. Johnson and C. Hansen. Harcourt Academic Press. (2004) pp. 875-900.

2. L.-C. Qin: Diffraction and Imaging of Single Walled Carbon Nanotubes. In: Electron Microscopy of Nanotubes and Nanowires; Eds. Z.L. Wang and C. Hui. (Kluwer Academic Publisher, 2003) pp.1-41.

3. L.-C. Qin: Electron Diffraction Method for Measuring the Atomic Structure of Carbon Nanotubes. In: Progress on Modern Electron Microscopy; Eds. Y.M. Wang, H.Q. Ye and K. Lu. (Academic Press, 2003) pp.55-83. (in Chinese)

4. J. Tang and L.-C. Qin, Deformation of Carbon Nanotubes under High Pressure; Future Materials 3(3), 2-5 (2003) (in Japanese).

5. L.-C. Qin: Electron Amorphography; in Progress in Transmission Electron Microscopy 1, Concepts and Techniques, Springer Series in Surface Sciences Vol. 38, Eds. X.F. Zhang and Z. Zhang, (Springer-Verlag / TUP, 2001), pp.223-244.

6. L.-C. Qin: Determining the Helicity of Carbon Nanotubes by Electron Diffraction; in Progress in Transmission Electron Microscopy 2, Applications in Materials Science, Springer Series in Surface Sciences Vol. 39, Eds. X.F. Zhang and Z. Zhang, (Springer-Verlag / TUP, 2001), pp.73-104.

7. L.-C. Qin, D.X. Li, and K.H. Kuo: High-Resolution Electron Microscopy of ZnS Crystals; Academic Press (1986). (in Chinese)

Manuscripts for Submission to Refereed Journals

8. L.-C. Qin, “Electron diffraction and holography of carbon nanotubes”; Reports on Progress in Physics (2005). (partially completed manuscript available)

9. Z. Liu and L.-C. Qin, “Measurement of relative handedness of multiwalled carbon nanotubes by electron diffraction”; to be submitted to Chemical Physics Letters (2005). (manuscript available)

10. G. Zhao, J. Zhang, Q. Zhang, J. Tang, O. Zhou and L.-C. Qin, “Fabrication and test of single nanotube emitter as point electron source”; to be submitted to Applied Physics Letters (2005). (manuscript available)

11. Q. Zhang, Z. Liu, A. Kleinhammes, Y. Wu, J. Tang, and L.-C. Qin, “Fine microstructure characterization of titanium oxide nanotubes”; to be submitted to Chemical Physics Letters (2005). (manuscript available)

12. H. Zhang, Q. Zhang, J. Zhang, O. Zhou, J. Tang and L.-C. Qin, “Fabrication and electric field-induced electron emission of LaB6 nanowires”; to be submitted to Advanced Materials (2005). (manuscript available)

13. H. Zhang, Q. Zhang, J. Tang, and L.-C. Qin, “One-step synthesis and TEM characterization of MgB2/MgO nanocables”; to be submitted to Chemical Physics Letters (2005). (manuscript available)

14. Q. Zhang, J. Tang, G. Yang, G. Zhao, O. Zhou, L-C. Qin, “Non-destructive TEM examination of carbon nanotube AFM tips”; to be submitted to Applied Physics Letters (2005). (manuscript available)

Manuscripts Submitted to Refereed Journals (in review)

15. Z. Liu and L-C. Qin, “A direct method to determine the chiral indices of carbon nanotubes”; submitted to Physical Review Letters (2005). (in review)

16. Z. Liu, Q. Zhang, and L.-C. Qin, “Accurate determination and mapping of diameter and helicity for single-walled carbon nanotubes using nanobeam electron diffraction”; submitted to Physical Review B (2005). (in review)

17. Z. Liu and L.-C. Qin, “Extinction and orientational dependence of electron diffraction from carbon nanotubes”; submitted to Physical Review B (2005). (in review)

18. Z. Liu, Q. Zhang, and L.-C. Qin, “Accurate determination of atomic structure of multiwalled carbon nanotubes by nondestructive nanobeam electron diffraction”; submitted to Applied Physics Letters (2005). (in review)

19. Z. Liu and L.-C. Qin, “Electronic structure of TiO2 nanotubes”; submitted to Solid State Communications (2005). (in review)

20. Z. Liu and L.-C. Qin, “Structure and energetics of carbon nanotube ropes”; submitted to Carbon (2005). (in review)

21. J. Li, Q. Zhang, H. Peng, H.O. Everitt, L.-C. Qin, and J. Liu, “Template-free and controlled growth of vertically aligned single crystal ZnO nanowire arrays on amorphous surfaces”; Journal of Physical Chemistry B (2004) (in review).

Manuscripts Accepted for Publication / in Press

22. Z. Liu and L.-C. Qin, “Electron diffraction from elliptical nanotubes”; submitted to Chemical Physics Letters (2005). (accepted for publication)

23. Z. Liu and L.-C. Qin, “A practical approach to determine the handedness of chiral carbon nanotubes by electron diffraction”; submitted to Chemical Physics Letters (2005). (accepted for publication)

24. H. Zhang, Q. Zhang, J. Tang, and L.-C. Qin, “Single-crystalline LaB6 nanowires”; submitted to Journal of American Chemical Society (2005). (in press)

25. Y.Y. Wang, S. Gupta, J.M. Garguilo, Z.J. Liu, L.-C. Qin, and R.J. Nemanich, “Growth and field emission properties of small diameter carbon nanotube films”; Diamond and Related Materials (2005) (accepted for publication).

Papers Published in Refereed Journals

26. Z. Liu and L.-C. Qin, “Breakdown of 2mm symmetry in electron diffraction from multiwalled carbon nanotubes”; Chemical Physics Letters 402, 202-205 (2005).

27. J. Tang, G. Yang, Q. Zhang., A. Parhat, B. Maynor, J. Liu, L.-C. Qin, O. Zhou, “Rapid and reproducible fabrication of carbon nanotube AFM probes by dielectrophoresis”; Nano Letters 5, 11-14 (2005).

28. Z. Liu and L.-C. Qin, “Symmetry of electron diffraction from single-walled carbon nanotubes”; Chemical Physics Letters 400, 430-435 (2004).

29. J. Zhang, J. Tang, G. Yang, Q. Qiu, L.-C. Qin, and O. Zhou, “Efficient Fabrication of Carbon Nanotube Point Electron Sources by Dielectrophoresis”; Advanced Materials 16, 1219-1222 (2004).

30. J. Tang, B. Gao, H. Geng, O.D.Velev, L.-C. Qin, and O. Zhou, “Assembly of 1D Nanostructures into sub-micron diameter fibrils with controlled and variable length by dielectrophoresis”; Advanced Materials 15, 1352-1355 (2003).

31. L.W. Hobbs, X.L. Yuan, L.-C. Qin, V. Pulim and A. Coventry, “The nanostructures of amorphous silicas”; Microscopy and Microanalysis 8(1), 29-34 (2002).

32. J. Tang, L.-C. Qin, H-W Gu, A. Matsushita, Y. Takano, K. Togano, H. Kito and H. Ihara, “Structure and electronic properties of superconductor MgB2 under high pressure”; Journal of Physics: Condensed Matter 14, 10623-10626 (2002).

33. J. Tang, L.-C. Qin, T. Sasaki, M. Yudasaka, A. Matsushita and S. Iijima, “Revealing properties of single-walled carbon nanotubes under high pressure”; Journal of Physics: Condensed Matter 14, 10575-10578 (2002).

34. X. Zhao, Y. Ando, L.-C. Qin, H. Kataura, Y. Maniwa and R. Saito, “Multiple splitting of G-band modes from individual multiwalled carbon nanotubes”; Appllied Physics Letters 81, 2550-2552 (2002).

35. X. Zhao, Y. Ando, L.-C. Qin, H. Kataura, Y. Maniwa and R. Saito, “Radial breathing modes of multiwalled carbon nanotubes”; Chemical Physics Letters 361, 169-174 (2002).

36. X. Zhao, Y. Ando, L.-C. Qin, H. Kataura, Y. Maniwa and R. Saito, “Characteristic Raman spectra of multiwalled carbon nanotubes”; Physica B - Condensed Matter 323, 265-266 (2002).

37. S. Iijima and L.-C. Qin, “Electron microscopic characterization of silver nanowire arrays”; Science 296, 611 (2002).

38. L.-C. Qin, X. Zhao, K. Hirahara, Y. Ando and S. Iijima, “Electron microscopic imaging and contrast of smallest carbon nanotubes”; Chemical Physics Letters 349, 389-393 (2001).

39. J. Tang, L.-C. Qin, A. Matsushita, Y. Takano, K. Togano, H. Kito and H. Ihara, “Lattice parameter and Tc dependence of sintered MgB2 superconductor on hydrostatic pressure”; Physical Review B 64, 132509 (2001).

40. M.J. Lopez, A. Rubio, J.A. Alonso, L.-C. Qin and S. Iijima, “New polygonized phase of single wall carbon nanotube bundles”; Physical Review Letters 86, 3056-3059 (2001).

41. J. Tang, L.-C. Qin, T. Sasaki, M. Yudasaka, A. Matsushita and S. Iijima, “Structure and property changes of single-walled carbon nanotubes under pressure”; Synthetic Metals 121, 1245-1246 (2001).

42. M. Yudasaka, H. Kataura, T. Ichihashi, L.-C. Qin, S. Kar and S. Iijima, “Diameter enhancement of HiPCo single-wall carbon nanotubes by heat treatment”; Nano Letters 1, 487-489 (2001).

43. L.-C. Qin, X. Zhao, K. Hirahara, Y. Miyamoto, Y. Ando and S. Iijima, “The smallest carbon nanotube”; Nature 408, 50 (2000).

44. J. Tang, L.-C. Qin, T. Sasaki, M. Yudasaka, A. Matsushita and S. Iijima, “Compressibility and polygonization of single-walled carbon nanotubes under hydrostatic pressure”; Physical Review Letters 85, 1887-1889 (2000).

45. L.-C. Qin, “Helical diffraction from tubular structures”; Materials Characterization 44, 407-412 (2000).

46. S. Bandow, F. Kokai, K. Takahashi, M. Yudasaka, L.-C. Qin, S. Iijima, “Interlayer spacing anomaly of single-wall carbon nanohorn aggregate”; Chemical Physics Letters 321, 514-519 (2000).

47. L.-C. Qin, “Measuring the true helicity of carbon nanotubes”; Chemical Physics Letters 297, 23-28 (1998).

48. L.C. Qin, D. Zhou, D.M. Gruen and A.R. Krauss, “Growing carbon nanotubes by microwave plasma-enhanced chemical vapor deposition”; Applied Physics Letters 72, 3437-3439 (1998).

49. L.C. Qin, D. Zhou, A.R. Krauss and D.M. Gruen, “TEM characterization of nanodiamond thin films”; NanoStructured Materials 10, 649-660 (1998).

50. D. Zhou, D.M. Gruen, L.C. Qin, T.G. McCauley, A.R. Krauss, “Control of diamond film microstructure by Ar additions to CH4/H2 microwave plasmas”; Journal of Applied Physics 84, 1981-1989 (1998).

51. D. Zhou, T.G. McCauley, L.C. Qin, A.R. Krauss and D.M. Gruen, “Synthesis of nanocrystalline diamond thin films from Ar-CH4 microwave plasma”; Journal of Applied Physics 83, 540-543 (1998).

52. D. Zhou, A.R. Krauss, L.C. Qin, T.G. McCauley, D.M. Gruen, T.D. Corrigan, R.P.H. Chang and H. Gnaser, “Synthesis and electron field emission of nanocrystalline diamond thin films grown from N2/CH4 microwave plasmas”; Journal of Applied Physics 82, 4546-4550 (1997).

53. L.C. Qin and S. Iijima, “Structure and formation of raft-like bundles of single-walled helical carbon nanotubes produced by laser evaporation”; Chemical Physics Letters 269, 65-71 (1997).

54. L.C. Qin and S. Iijima, “Fibrilliform growth of carbon nanotubes”; Materials Letters 30, 311-314 (1997).

55. L.-C. Qin, “CVD synthesis of carbon nanotubes”; Journal of Materials Science Letters 16, 457-459 (1997).

56. L.C. Qin, T. Ichihashi and S. Iijima, “On the measurement of helicity of carbon nanotubes”; Ultramicroscopy 67, 181-189 (1997).

57. L.C. Qin, S. Iijima, H. Kitaura, Y. Maniwa, S. Suzuki and Y. Achiba, “Helicity and packing of single-walled carbon nanotubes studied by electron nanodiffraction”; Chemical Physics Letters 268, 101-106 (1997).

58. L.C. Qin and S. Iijima, Onion-like graphitic particles produced from diamond; Chemical Physics Letters 262, 252-258 (1996).

59. L.C. Qin and L.W. Hobbs, “Energy-filtered electron diffraction study of vitreous and amorphized silicas”; Journal of Non-Crystalline Solids 192&193, 456-462 (1995).

60. L.-C. Qin, “Electron diffraction from cylindrical nanotubes”; Journal of Materials Research 9, 2450-2456 (1994).

61. L.-C. Qin, “Comparison of x-ray and electron atomic scattering factors”; Biophysical Journal 61, 296 (1992).

62. L.-C. Qin and K. Urban, “Electron diffraction and lattice image simulations with the inclusion of HOLZ reflections”; Ultramicroscopy 33, 159-166 (1990).

63. P. Goodman, A.E.C. Spargo, L.-C. Qin and K. Ishizuka, “The top bottom N-beam phase-contrast effect from finite crystals. II. Theory”; Philosophical Magazine A61, 205-220 (1990).

64. Z.G. Xiao, X.W. Lin, G.Z. Liu, T. Ko and L.-C. Qin, “crystalline plate-like SiO2 precipitates in silicon and their relation with new donors”; Journal of Materials Science 24, 3573-3576 (1989).

65. L.-C. Qin and P. Goodman, “An alternative study of the reciprocity theorem in electron diffraction”; Ultramicroscopy 27, 115-116 (1989).

66. L.-C. Qin, “A further study on the self-consistent algebraic reconstruction algorithm”; Optik 76, 176-177 (1987).

67. D.F. Lynch and L.-C. Qin, “The multislice program for use on a PC-style desktop computer”; Journal of Applied Crystallography 20, 442-444 (1987).

68. Z.G. Xiao, L.-C. Qin and X.W. Lin, “Structure of plate-like oxygen precipitate in Czochralski-grown silicon”; Materials Science and Engineering 92, L9-L10 (1987).

69. L.-C. Qin, D.X. Li and K.H. Kuo, “An HREM study of the defects in ZnS”; Philosophical Magazine A53, 543-555 (1986).

Conference Proceedings / Extended Abstracts

70. H. Zhang, Q. Zhang and L.-C. Qin, “Synthesis and TEM characterization of MgB2/MgO nanocables”; Microscopy & Microanalysis 10 (Suppl. 2), p.364 (2004).

71. Z. Liu and L.-C. Qin, “Determination of helicity and diameter of nanotubes in a triple-tubule bundle”; Microscopy & Microanalysis 10 (Suppl. 2), p.372 (2004).

72. Q. Zhang, J. Tang, G. Yang, G. Zhao, O. Zhou and L.-C. Qin, “Non-destructive examination of carbon nanotube AFM probes by HREM”; Microscopy & Microanalysis 10 (Suppl. 2), p.548 (2004).

73. G. Zhao, J. Zhang, Q. Zhang J. Tang, O. Zhou and L.-C. Qin, “Fabrication and test of single nanotube emitter as point electron source”; Microscopy & Microanalysis 10 (Suppl. 2), p.550 (2004).

74. J. Tang, G. Yang, J. Zhang, H.Z. Geng, B. Bao, O. Velev, L.-C. Qin, and O. Zhou, “Controlled assembly of carbon nanotube fibrils by dielectrophoresis”; Materials Research Society Symposium Proceedings 788, 539-544 (2004).

75. J. Tang, L.-C. Qin, and T. Sasaki, “Compressibility of fullerene-filled carbon nanotubes”; Proceedings of 19th International Conference on High Pressure Science and Technology (Bordeaux, 2003).

76. J. Tang, L.-C. Qin, M. Yudasaka, A. Matsushita, T. Kikegawa and S. Iijima, “In situ measurement of the morphological and property changes of single-walled carbon nanotubes under pressure”; Proceedings of the 8th NIRIM International Symposium (ISAM 2001), p. 109 (National Institute for Research in Inorganic Materials, Tsukuba, Japan, 2001).

77. L.-C. Qin, K. Hirahara, X. Zhao, Y. Ando and S. Iijima, “Imaging of 4Å carbon nanotubes”; Electron Microscopy 36 Supp. 1, 168 (2001).

78. L.-C. Qin, J. Tang, T. Sasaki, M. Yudasaka, A. Matsushita and S. Iijima, “Structural and electronic property changes of single-walled carbon nanotubes under pressure”; American Institute of Physics Conference Proceedings 590, 205-208 (2001).

79. D.M. Gruen, L.A. Curtiss, P.C. Redfern and L.-C. Qin, “Nucleation of nanocrystalline diamond by fragmentation of fullerene precursors”; Fullerenes 6: Recent Advances in the Chemistry and Physics of Fullerenes and Related Materials, 509-514 (1998).

80. A.R. Krauss, D.M. Gruen, D. Zhou, T.G. McCauley, L.-C. Qin, T. Corrigan, O. Auciello and R.P.H. Chang, “Morphology and electron emission properties of nanocrystalline CVD diamond thin films”, Materials Research Society Symposium Proceedings 495, 299-307 (1998).

81. L.-C. Qin, T. Ichihashi and S. Iijima, “Spherical carbon clusters obtained from diamond”; Fullerene 3: Recent Advances in the Chemistry and Physics of Fullerenes and Related Materials, 661-666 (1997).

82. L.-C. Qin, M. Yudasaka, S. Iijima, F. Kokai and K. Takahashi, “Transformation of nano-horns into nano-onions in electron beam”; Electron Microscopy 35 Supp. 1, 46 (2000).

83. K. Hirahara, X. Zhao, Y. Ando, S. Iijima and L.C. Qin, “Formation model of smallest carbon nanotubes”; Electron Microscopy 35 Supp. 1, 54 (2000).

84. L.-C. Qin, X. Zhao, Y. Ando and S. Iijima, “What is the smallest carbon nanotube?”; Proceedings of 7th Asia-Pacific Electron Microscopy Conference – Physical Sciences, p.134 (2000).

85. L.-C. Qin, X. Zhao, Y. Ando and S. Iijima, “Smallest carbon nanotubes”; Proceedings of The 18th Fullerene General Symposium, p.11 (Fullerene Research Association, Okasaki, Japan, 2000).

86. L.-C. Qin, J. Tang, A. Matsushita, M. Yudasaka and S. Iijima, “Elastic deformation of single-walled carbon nanotubes under hydrostatic pressure”; Proceedings of The 18th Fullerene General Symposium, p.27 (Fullerene Research Association, Okasaki, Japan, 2000).

87. L.-C. Qin and S. Iijima, “Twisting of single-walled carbon nanotube bundles”; Materials Research Society Symposium Proceedings 593, 33-36 (2000).

88. J. Tang, L.-C. Qin, A. Matsushita, T. Kikegawa, M. Yudasaka, S. Bandow and S. Iijima, “Study of carbon nanotubes under high pressure”; Materials Research Society Symposium Proceedings 593, 179-183 (2000).

89. L.-C. Qin and S. Iijima, “Helicity-induced deformation of carbon nanotubes in bundles”; The 54th Japanese Physical Society Fall Meeting, 24pYL-12 (Morioka, Japan, 1999).

90. L.-C. Qin. T. Ichihashi and S. Iijima, “CVD synthesis of carbon nanotubes”; 11th Fullerene General Symposium, Saporo, Japan, August 1996).

91. L.C. Qin, T. Ichihashi and S. Iijima, Synthesis and structure of CVD-grown carbon nanotubes; The 51st Spring Meeting of the Japanese Physical Society, p. 2733 (Kanazawa, Japan, 1996).

92. L.C. Qin, T. Ichihashi and S. Iijima, “An analysis of electron diffraction from carbon nanotubes”; Proceedings of 51st Annual Meeting of the Japanese Electron Microscopy Society, (Sakai, Japan, 24-26 May 1995).

93. L.-C. Qin and L.W. Hobbs, “Medium-range order in metamict silicas”; Materials Research Society Symposium Proceedings 373, 341-346 (1995).

94. L.-C. Qin and L.W. Hobbs, “Quantitative HREM of electron-irradiated quartz”; Materials Research Society Symposium Proceedings 373, 329-334 (1995).

95. L.-C. Qin and L.W. Hobbs, “On the determination of partial RDFs for amorphous materials”; Materials Research Society Symposium Proceedings 321, 39-44 (1994).

96. L.-C. Qin, HREM of electron-irradiated silicas; Proceedings of 51st Annual Meeting of Microscopy Society of America, p.1102 (1993).

97. M.E. Lewis, L.-C. Qin, A.N. Sreeram and L.W. Hobbs, Processing of high resolution images of irradiated ceramics; Proceedings of 51st Annual Meeting of Microscopy Society of America, p.1230 (1993).

98. L.-C. Qin and L.W. Hobbs, “Energy-filtered electron diffraction from silica thin films”; Materials Research Society Symposium Proceedings 284, 331-336 (1993).

99. L.-C. Qin and L.W. Hobbs, “HREM of electron-irradiated quartz”; Materials Research Society Symposium Proceedings 279, 387-392 (1993).

100. L.-C. Qin, A. Garratt-Reed and L.W. Hobbs, Theory and practice of energy-filtered electron diffraction using the HB5 STEM; Proceedings of 50th Annual Meeting of Microscopy Society of America, p.350 (1992).

101. A.N. Sreeram, L.-C. Qin, A. Garratt-Reed and L.W. Hobbs, Characterization of metamict and glassy phosphates using energy-filtered electron diffraction; Proceedings of 50th Annual Meeting of Microscopy Society of America, p.1274 (1992).

102. L.-C. Qin, K. Urban, D. Gratias and M. Wilkens, Multislice simulation of quasicrystal lattice images; Proceedings of 5th Asia-Pacific Conference of Electron Microscopy (1992).

103. L.-C. Qin and L.D. Marks, Electron diffraction contrast of fluxons; Proceedings of 49th Annual Meeting of Electron Microscopy Society of America, p.1102 (1991).

104. D.J. Li, J.P. Zhang, L.-C. Qin and L.D. Marks, Indication of flux pinning by chemical defects in 123; Electron Microscopy 1990, p.54 (1990).

105. I.K. Jordan, A.R. Preston, L.C. Qin and J.W. Steeds, “Analysis of LACBED patterns from InP/InGaAs multiple quantum-well samples by dynamic theory”; Institute of Physics Conference Series 98, 131-134 (1990).

106. J.W. Steeds, L.-C. Qin and I.K. Jordan, “Characterization of defects and buried interfaces in quantum well structures by combination of LACBED and microscopic CL in a TEM”; Materials Research Society Symposium Proceedings 138, 427-430 (1989).

107. A.R. Preston, L.-C. Qin, I.K. Jordan and J.W. Steeds, EMAG’89 (1989).

108. L.-C. Qin, D.X. Li and K.H. Kuo, “A direct study of the end-on dislocations in ZnS by HREM”; Proceedings of Beijing Conference and Exhibition on Instrumental Analysis, pp.219-223 (Beijing, 1985).

109. L.-C. Qin, D.X. Li and K.H. Kuo, “HREM investigations of the microtwins in ZnS doped with Cu and Mn”; Journal of Chinese Electron Microscopy 5, 1984.

Book Review

110. L.-C. Qin, Book review in Microscopy and Analysis (March 2002). Electron Diffraction in the Transmission Electron Microscope, by P.E. Champness (Oxford: BIOS Scientific Publishers, 2001).

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