Quartz tuning fork-based frequency modulation atomic force spectroscopy and microscopy with all digital phase-locked loop

Sangmin An; Mun Heon Hong; Jongwoo Kim; Soyoung Kwon; Kunyoung Lee; Manhee Lee; Wonho Jhe

doi:10.1063/1.4765702

Quartz tuning fork-based frequency modulation atomic force spectroscopy and microscopy with all digital phase-locked loop

Sangmin An^*
, Mun Heon Hong
, Jongwoo Kim
, Soyoung Kwon
, Kunyoung Lee
, Manhee Lee
, Wonho Jhe

^*Corresponding author for this work

Department of Physics

Seoul National University
LG Corporation
Harvard University

Research output: Contribution to journal › Journal article › peer-review

8 Scopus citations

Abstract

We present a platform for the quartz tuning fork (QTF)-based, frequency modulation atomic force microscopy (FM-AFM) system for quantitative study of the mechanical or topographical properties of nanoscale materials, such as the nano-sized water bridge formed between the quartz tip (∼100 nm curvature) and the mica substrate. A thermally stable, all digital phase-locked loop is used to detect the small frequency shift of the QTF signal resulting from the nanomaterial-mediated interactions. The proposed and demonstrated novel FM-AFM technique provides high experimental sensitivity in the measurement of the viscoelastic forces associated with the confined nano-water meniscus, short response time, and insensitivity to amplitude noise, which are essential for precision dynamic force spectroscopy and microscopy.

Original language	English
Article number	113705
Journal	Review of Scientific Instruments
Volume	83
Issue number	11
DOIs	https://doi.org/10.1063/1.4765702
State	Published - 2012.11

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title = "Quartz tuning fork-based frequency modulation atomic force spectroscopy and microscopy with all digital phase-locked loop",

abstract = "We present a platform for the quartz tuning fork (QTF)-based, frequency modulation atomic force microscopy (FM-AFM) system for quantitative study of the mechanical or topographical properties of nanoscale materials, such as the nano-sized water bridge formed between the quartz tip (∼100 nm curvature) and the mica substrate. A thermally stable, all digital phase-locked loop is used to detect the small frequency shift of the QTF signal resulting from the nanomaterial-mediated interactions. The proposed and demonstrated novel FM-AFM technique provides high experimental sensitivity in the measurement of the viscoelastic forces associated with the confined nano-water meniscus, short response time, and insensitivity to amplitude noise, which are essential for precision dynamic force spectroscopy and microscopy.",

author = "Sangmin An and Hong, \{Mun Heon\} and Jongwoo Kim and Soyoung Kwon and Kunyoung Lee and Manhee Lee and Wonho Jhe",

year = "2012",

month = nov,

doi = "10.1063/1.4765702",

language = "English",

volume = "83",

journal = "Review of Scientific Instruments",

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T1 - Quartz tuning fork-based frequency modulation atomic force spectroscopy and microscopy with all digital phase-locked loop

AU - An, Sangmin

AU - Hong, Mun Heon

AU - Kim, Jongwoo

AU - Kwon, Soyoung

AU - Lee, Kunyoung

AU - Lee, Manhee

AU - Jhe, Wonho

PY - 2012/11

Y1 - 2012/11

N2 - We present a platform for the quartz tuning fork (QTF)-based, frequency modulation atomic force microscopy (FM-AFM) system for quantitative study of the mechanical or topographical properties of nanoscale materials, such as the nano-sized water bridge formed between the quartz tip (∼100 nm curvature) and the mica substrate. A thermally stable, all digital phase-locked loop is used to detect the small frequency shift of the QTF signal resulting from the nanomaterial-mediated interactions. The proposed and demonstrated novel FM-AFM technique provides high experimental sensitivity in the measurement of the viscoelastic forces associated with the confined nano-water meniscus, short response time, and insensitivity to amplitude noise, which are essential for precision dynamic force spectroscopy and microscopy.

AB - We present a platform for the quartz tuning fork (QTF)-based, frequency modulation atomic force microscopy (FM-AFM) system for quantitative study of the mechanical or topographical properties of nanoscale materials, such as the nano-sized water bridge formed between the quartz tip (∼100 nm curvature) and the mica substrate. A thermally stable, all digital phase-locked loop is used to detect the small frequency shift of the QTF signal resulting from the nanomaterial-mediated interactions. The proposed and demonstrated novel FM-AFM technique provides high experimental sensitivity in the measurement of the viscoelastic forces associated with the confined nano-water meniscus, short response time, and insensitivity to amplitude noise, which are essential for precision dynamic force spectroscopy and microscopy.

UR - https://www.scopus.com/pages/publications/84870509617

U2 - 10.1063/1.4765702

DO - 10.1063/1.4765702

M3 - Journal article

AN - SCOPUS:84870509617

SN - 0034-6748

VL - 83

JO - Review of Scientific Instruments

JF - Review of Scientific Instruments

IS - 11

M1 - 113705

ER -

Quartz tuning fork-based frequency modulation atomic force spectroscopy and microscopy with all digital phase-locked loop

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