[1] 沈素丹, 郑娜, 浦群, 等. 透射电子显微镜-能谱中载网支持膜所含杂质成分的影响与分析[J]. 电子显微学报, 2021, 40(5): 616-622.
[2] 王毅苗, 安娇娜, 李树铁. 应用透射电子显微镜观察重症急性胰腺炎组织的超微结构——电子显微镜技术在医学领域的应用[J]. 电子显微学报, 2020, 39(3): 344.
[3] 丁青青, 贝红斌, 赵新宝, 等. 透射电子显微学在镍基单晶高温合金领域的应用进展和展望[J]. 电子显微学报, 2020, 39(5): 586-602.
[4] HAIDER M, BRAUNSHAUSEN G, SCHWAN E. Correction of the spherical of a 200 kV TEM by means of a hexapole-corrector[J]. Optik(Stuttgart), 1995, 99(4), 167-179.
[5] 时金安, 胡书广, 夏艳, 等. 单色球差校正扫描透射电子显微镜的实验室设计[J]. 电子显微学报, 2020, 39(6): 715-721.
[6] TAYLOR K A, GLAESER R M. Retrospective on the early development of Cryoelectron microscopy of macromolecules and a prospective on opportunities for the future[J]. Journal of Structural Biology, 2008, 163(3): 214-223.
[7] FRANK J. Time-resolved Cryo-electron microscopy: Recent progress[J]. Journal of Structural Biology, 2017, 200(3): 303-306.
[8] AHMED H, ZEWAIL J, THOMAS M. 梁文锡等译. 四维电子显微镜: 在空间和时间中成像[M]. 武汉: 华中科技大学出版社, 2016.
[9] DAVID B, WILLIAMS C, BARRY C. Transmission electron microscopy: a textbook for material science[M]. 2nd. New York: Springer, 2009.
[10] 王宏伟. 冷冻电子显微学在结构生物学研究中的现状与展望[J]. 中国科学: 生命科学, 2014, 44(10): 1020-1028.
[11] 黄兰友, 刘绪平. 电子显微镜与电子光学[M]. 北京: 科学出版社, 1991.
[12] 洪涛. 生物医学超微结构与电子显微镜技术[M]. 北京: 科学出版社, 1980.
[13] HOUDELLIER F, CARUSO G M, WEBER S, et al. Development of a high brightness ultrafast transmission electron microscope based on a laser-driven cold field emission source[J]. Ultramicroscopy. 2018, 186: 128-138.
[14] 姚骏恩. 电子显微镜的现状与展望[J]. 电子显微学报, 1998, 17(6): 81-90.
[15] TROMP R M. Low-energy electron microscopy[J]. IBM Journal of Research and Development, 2000, 44(4): 503-516.
[16] LONGCHAMP J N, LATYCHEVSKAIA T, ESCHER C, et al. Low-energy electron holographic imaging of individual tobacco mosaic virions[J]. Applied Physics Letters, 2015, 107(13): 133101.
[17] BARTON B, JOOS F, SCHRÖDER R R. Improved specimen reconstruction by Hilbert phase contrast tomography[J]. Journal of Structural Biology, 2008, 164(2): 210-220.
[18] MAJOROVITSE, BARTON B,SCHULTHEISSK, et al. Optimizing phase contrast in transmission electron microscopy with an electrostatic (Boersch) phase plate[J]. Ultramicroscopy, 2007, 107(2-3): 213-226.
[19] SCHULTHEISS K, PÉREZ-WILLARD F, BARTON B, et al. Fabrication of a Boersch phase plate for phase contrast imaging in a transmission electron microscope[J]. Review of Scientific Instruments, 2006, 77(3): 033701-033704.
[20] LI W P, HAN L. N-body Monte Carlo simulation on high contrast biology transmission electron microscope[J]. Journal of Biological Systems, 2010, 18(1): 177-186.
[21] ASSAIYA A, BURADA A P, DHINGRA S, et al. An overview of the recent advances in Cryo-electron microscopy for life sciences[J]. Emerging Topics in Life Sciences, 2021, 5(1): 151-168.
[22] LIAO M., CAO E H, JULIUS D, et al. Structure of the TRPV1 ion channel determined by electron Cryo-microscopy[J]. Nature, 2013, 504(7478): 107-112.
[23] CAO E H, LIAO M F, CHENG Y F, et al. TRPV1 structures in distinct conformations reveal activation mechanisms[J]. Nature, 2013, 504(7478): 113-118.
[24] PUTNAM W P, YANIK M F. Noninvasive electron microscopy with interaction-free quantum measurements[J]. Physical Review A, 2009, 80(4): 040902.
[25] GIOVANNETTI V, LLOYD S, MACCONE L. Quantum-enhanced measurements: Beating the standard quantum limit[J]. Science, 2004, 306(5700): 1330-1336.
[26] OKAMOTO H, LATYCHEVSKAIA T, FINK H W. A quantum mechanical scheme to reduce radiation damage in electron microscopy[J]. Applied Physics Letters, 2006, 88(16): 171.
[27] AGARWAL A, BERGGREN K K, VAN STAADEN Y J, et al. Reduced damage in electron microscopy by using interaction-free measurement and conditional re-illumination[J]. Physics Review A, 2019, 99(6): 063809.
[28] LI W P, KIM C S, et al. Design and numerical analysis of a coherent electron resonator for the quantum electron microscope[C]. In: The 60th international conference on electron, ion, and photon beam technology and nanofabrication. Pittsburgh, 2016.
[29] YANG Y J, KIM C S, HOBBS R G, et al. Nanostructured-membrane electron phase plates[J]. Ultramicroscopy, 2020, 217: 113053.
[30] TURNER A E, JOHNSON C W, KRUIT P, et al. Interaction-free measurement with electrons[J]. Physical Review Letters, 2021, 127(11): 110401.
[31] ELITZUR A C, VAIDMAN L. Quantum mechanical interaction-free measurements[J]. Foundations of Physics, 1993, 23(7): 987-997.
[32] KWIAT P, WEINFURTER H, HERZOG T, et al. Interaction-free measurement[J]. Physical Review Letters, 1995, 74(24): 4763-4766.
[33] KWIAT P G, WHITE A G, MITCHELL J R, et al. High-efficiency quantum interrogation measurements via the quantum Zeno effect [J]. Physical Review Letters, 1999, 83(23): 4724-4728.
[34] NAMEKATA N, INOUE S. High-efficiency interaction-free measurements using a stabilized Fabry–Pérot cavity[J]. Journal of Physics B-Atomic Molecular & Optical Physics, 2006, 39(16): 3177-3183.
[35] KRUIT P, HOBBS R G, KIM C S, et al. Designs for a quantum electron microscope[J]. Ultramicroscopy, 2016, 164: 31-45.
[36] AGARWAL A, KIM C S, HOBBS R, et al. A nanofabricated, monolithic, path-separated electron interferometer[J]. Scientific Reports, 2017, 7(1): 1677.
[37] HARVEY T R, PIERCE J S, AGRAWAL A K, et al. Efficient diffractive phase optics for electrons[J]. New Journal of Physics, 2014, 16(9): 093039.
[38] MATTEUCCI G, MISSIROLI G F, POZZI G. Amplitude division electron interferometry[J]. Ultramicroscopy, 1981, 6(2): 109-113.
[39] COWLEY J M. Twenty forms of electron holography[J]. Ultramicroscopy, 1992, 41(4): 335-348.
[40] YANG Y J, KIM S-C, HOBBS R G, et al. Efficient two-port electron beam splitter via a quantum interaction-free measurement[J]. Physics Review A, 2018, 98(4): 043621.