Active Q control in tuning-fork-based atomic force microscopy

被引:24
作者
Jahng, Junghoon
Lee, Manhee
Noh, Hanheol
Seo, Yongho
Jhe, Wonho [1 ]
机构
[1] Seoul Natl Univ, Dept Physiol & Anat, Seoul 151747, South Korea
[2] Sejong Univ, Inst Fundamental Phys, Dept Nanotechnol, Seoul, South Korea
来源
APPLIED PHYSICS LETTERS | 2007年 / 91卷 / 02期
关键词
CANTILEVERS; RESOLUTION;
D O I
10.1063/1.2753112
中图分类号
O59 [应用物理学];
学科分类号
摘要
The authors present comprehensive theoretical analysis and experimental realization of active Q control for the self-oscillating quartz tuning fork (TF). It is shown that the quality factor Q can be increased (decreased) by adding the signal of any phase lag, with respect to the drive signal, in the range of theta(1) to theta(1)+pi (theta(1)+pi to theta(1)+2 pi), where theta(1) is the characteristic constant of TF. Experimentally, the nominal Q value of 4.7x10(3) is decreased to 1.8x10(3) or increased to 5.0x10(4) in ambient condition, where the minimum detectable force is estimated to be 4.9x10(-14) N at 1 Hz. The novel Q control scheme demonstrated in the widely used quartz TF is expected to contribute much to scanning probe microscopy of, in particular, soft and biological materials. (C) 2007 American Institute of Physics.
引用
收藏
页数:3
相关论文
共 50 条
  • [21] Mechanically Stable Tuning Fork Sensor With High Quality Factor for the Atomic Force Microscope
    Kim, Kwangyoon
    Park, Jun-Young
    Kim, K. B.
    Lee, Naesung
    Seo, Yongho
    SCANNING, 2014, 36 (06) : 632 - 639
  • [22] A measurement of the hysteresis loop in force-spectroscopy curves using a tuning-fork atomic force microscope
    Lange, Manfred
    van Voerden, Dennis
    Moeller, Rolf
    BEILSTEIN JOURNAL OF NANOTECHNOLOGY, 2012, 3 : 207 - 212
  • [23] Quartz tuning fork-based conductive atomic force microscope with glue-free solid metallic tips
    Botaya, Luis
    Otero, Jorge
    Gonzalez, Laura
    Coromina, Xavier
    Gomila, Gabriel
    Puig-Vidal, Manel
    SENSORS AND ACTUATORS A-PHYSICAL, 2015, 232 : 259 - 266
  • [24] High quality-factor quartz tuning fork glass probe used in tapping mode atomic force microscopy for surface profile measurement
    Chen, Yuan-Liu
    Xu, Yanhao
    Shimizu, Yuki
    Matsukuma, Hiraku
    Gao, Wei
    MEASUREMENT SCIENCE AND TECHNOLOGY, 2018, 29 (06)
  • [25] Force spectroscopy by dynamic atomic force microscopy on bovine serum albumin proteins changing the tip hydrophobicity, with piezoelectric tuning fork self-sensing scanning probe
    Polesel-Maris, Jerome
    Legrand, Jeremy
    Berthelot, Thomas
    Garcia, Alexandre
    Viel, Pascal
    Makky, Ali
    Palacin, Serge
    SENSORS AND ACTUATORS B-CHEMICAL, 2012, 161 (01): : 775 - 783
  • [26] High resolution atomic force microscopy with an active piezoelectric microcantilever
    Nasrabadi, Hazhir Mahmoodi
    Mahdavi, Mohammad
    Soleymaniha, Mohammadreza
    Moheimani, S. O. Reza
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2022, 93 (07)
  • [27] Structural Analysis of Ionic-liquid/Organic-monolayer Interface by Phase Modulation Atomic Force Microscopy Utilizing a Quartz Tuning Fork Sensor
    Ichii, Takashi
    Negami, Masahiro
    Fujimura, Motohiko
    Murase, Kuniaki
    Sugimura, Hiroyuki
    ELECTROCHEMISTRY, 2014, 82 (05) : 380 - 384
  • [28] Numerical performance analysis of quartz tuning fork-based force sensors
    Dagdeviren, Omur E.
    Schwarz, Udo D.
    MEASUREMENT SCIENCE AND TECHNOLOGY, 2017, 28 (01)
  • [29] Evaluation and optimization of quartz resonant-frequency retuned fork force sensors with high Q factors, and the associated electric circuits, for non-contact atomic force microscopy
    Ooe, Hiroaki
    Fujii, Mikihiro
    Tomitori, Masahiko
    Arai, Toyoko
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2016, 87 (02)
  • [30] Active Microcantilevers for High Material Contrast in Harmonic Atomic Force Microscopy
    Schuh, Andreas
    Hofer, Manuel
    Ivanov, Tzvetan
    Rangelow, Ivo W.
    JOURNAL OF MICROELECTROMECHANICAL SYSTEMS, 2015, 24 (05) : 1622 - 1631
12345