Calculation of the optimal imaging parameters for frequency modulation atomic force microscopy

被引:147
|
作者
Giessibl, FJ [1 ]
Bielefeldt, H [1 ]
Hembacher, S [1 ]
Mannhart, J [1 ]
机构
[1] Univ Augsburg, Inst Phys Elect Correlat & Magnetism, D-86135 Augsburg, Germany
来源
APPLIED SURFACE SCIENCE | 1999年 / 140卷 / 3-4期
关键词
atomic force microscopy; frequency modulation atomic force microscopy; dynamic force microscopy; atomic resolution; tip-sample interaction; dissipation; thermal noise;
D O I
10.1016/S0169-4332(98)00553-4
中图分类号
O64 [物理化学(理论化学)、化学物理学];
学科分类号
070304 ; 081704 ;
摘要
True atomic resolution of conductors and insulators is now routinely obtained in vacuum by frequency modulation atomic force microscopy. So far, the imaging parameters (i.e., eigenfrequency, stiffness and oscillation amplitude of the cantilever, frequency shift) which result in optimal spatial resolution for a given cantilever and sample have been found empirically. Here, we calculate the optimal set of parameters from first principles as a function of the tip-sample system. The result shows that the tither the acquisition rate or the signal-to-noise ratio could be increased by up to two orders of magnitude by using stiffer cantilevers and smaller amplitudes than an in use today. (C) 1999 Elsevier Science B.V. All rights reserved.
引用
收藏
页码:352 / 357
页数:6
相关论文
共 50 条
  • [1] A procedure to determine the optimum imaging parameters for atomic/molecular resolution frequency modulation atomic force microscopy
    Hosokawa, Yoshihiro
    Kobayashi, Kei
    Oyabu, Noriaki
    Matsushige, Kazumi
    Yamada, Hirofumi
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2010, 81 (09)
  • [2] Frequency noise in frequency modulation atomic force microscopy
    Kobayashi, Kei
    Yamada, Hirofumi
    Matsushige, Kazumi
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2009, 80 (04)
  • [3] Mapping and imaging for rapid atom discrimination: A study of frequency modulation atomic force microscopy
    Sugimoto, Yoshiaki
    Namikawa, Takashi
    Abe, Masayuki
    Morita, Seizo
    APPLIED PHYSICS LETTERS, 2009, 94 (02)
  • [4] Calculation of the frequency shift in dynamic force microscopy
    Hölscher, H
    Schwarz, UD
    Wiesendanger, R
    APPLIED SURFACE SCIENCE, 1999, 140 (3-4) : 344 - 351
  • [5] Modelling and nanoscale force spectroscopy of frequency modulation atomic force microscopy
    Payam, Amir Farokh
    APPLIED MATHEMATICAL MODELLING, 2020, 79 (79) : 544 - 554
  • [6] Hybrid mode atomic force microscopy of phase modulation and frequency modulation
    Yamamoto, Tatsuya
    Miyazaki, Masato
    Nomura, Hikaru
    Li, Yan Jun
    Sugawara, Yasuhiro
    MICROSCOPY, 2023, 72 (03) : 236 - 242
  • [7] Nanoscale lithography with frequency-modulation atomic force microscopy
    Hamada, Masayuki
    Eguchi, T.
    Akiyama, K.
    Hasegawa, Y.
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2008, 79 (12)
  • [8] Imaging defects on CaF2(111) surface with frequency modulation atomic force microscopy
    Fujii, S
    Fujihira, M
    JAPANESE JOURNAL OF APPLIED PHYSICS PART 1-REGULAR PAPERS BRIEF COMMUNICATIONS & REVIEW PAPERS, 2006, 45 (3B): : 1986 - 1991
  • [9] Understanding 2D atomic resolution imaging of the calcite surface in water by frequency modulation atomic force microscopy
    Tracey, John
    Miyazawa, Keisuke
    Spijker, Peter
    Miyata, Kazuki
    Reischl, Bernhard
    Canova, Filippo Federici
    Rohl, Andrew L.
    Fukuma, Takeshi
    Foster, Adam S.
    NANOTECHNOLOGY, 2016, 27 (41)
  • [10] The structure of uniaxially stretched isotactic polypropylene sheets: Imaging with frequency-modulation atomic force microscopy
    Uchida, Kiminori
    Mita, Kazuki
    Matsuoka, Osamu
    Isaki, Takeharu
    Kimura, Kenjiro
    Onishi, Hiroshi
    POLYMER, 2016, 82 : 349 - 355
12345