Energy loss triggered by atomic-scale lateral force

Filippo F. Canova; Shigeki Kawai; Christian de Capitani; Ken-ichi Kan'no; Thilo Glatzel; Bartosz Such; Adam S. Foster; Ernst Meyer

doi:10.1103/PhysRevLett.110.203203

Energy loss triggered by atomic-scale lateral force

Filippo F. Canova, Shigeki Kawai, Christian de Capitani, Ken-ichi Kan'no, Thilo Glatzel, Bartosz Such, Adam S. Foster, Ernst Meyer

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Abstract

We perform bimodal atomic force microscopy measurements on a Br-doped NaCl (001) surface to investigate the mechanisms behind frequency shift and energy dissipation contrasts. The peculiar pattern of the dissipated energy in the torsional channel, related to frictional processes, is increased at the positions of Br impurities, otherwise indistinguishable from Cl ions in the other measured channels. Our simulations reveal how the energy dissipates by the rearrangement of the tip apex and how the process is ultimately governed by lateral forces. Even the slightest change in lateral forces, induced by the presence of a Br impurity, is enough to trigger the apex reconstruction more often, thus increasing the dissipation contrast; the predicted dissipation pattern and magnitude are in good quantitative agreement with the measurements.

Original language	English
Article number	203203
Pages (from-to)	1-5
Journal	Physical Review Letters
Volume	110
Issue number	20
DOIs	https://doi.org/10.1103/PhysRevLett.110.203203
Publication status	Published - 2013
MoE publication type	A1 Journal article-refereed

Keywords

AFM
MD

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10.1103/PhysRevLett.110.203203

PhysRevLett.110.203203Final published version, 1.09 MB

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title = "Energy loss triggered by atomic-scale lateral force",

abstract = "We perform bimodal atomic force microscopy measurements on a Br-doped NaCl (001) surface to investigate the mechanisms behind frequency shift and energy dissipation contrasts. The peculiar pattern of the dissipated energy in the torsional channel, related to frictional processes, is increased at the positions of Br impurities, otherwise indistinguishable from Cl ions in the other measured channels. Our simulations reveal how the energy dissipates by the rearrangement of the tip apex and how the process is ultimately governed by lateral forces. Even the slightest change in lateral forces, induced by the presence of a Br impurity, is enough to trigger the apex reconstruction more often, thus increasing the dissipation contrast; the predicted dissipation pattern and magnitude are in good quantitative agreement with the measurements.",

keywords = "AFM, MD, AFM, MD, AFM, MD",

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AU - F. Canova, Filippo

AU - Kawai, Shigeki

AU - de Capitani, Christian

AU - Kan'no, Ken-ichi

AU - Glatzel, Thilo

AU - Such, Bartosz

AU - Foster, Adam S.

AU - Meyer, Ernst

PY - 2013

Y1 - 2013

N2 - We perform bimodal atomic force microscopy measurements on a Br-doped NaCl (001) surface to investigate the mechanisms behind frequency shift and energy dissipation contrasts. The peculiar pattern of the dissipated energy in the torsional channel, related to frictional processes, is increased at the positions of Br impurities, otherwise indistinguishable from Cl ions in the other measured channels. Our simulations reveal how the energy dissipates by the rearrangement of the tip apex and how the process is ultimately governed by lateral forces. Even the slightest change in lateral forces, induced by the presence of a Br impurity, is enough to trigger the apex reconstruction more often, thus increasing the dissipation contrast; the predicted dissipation pattern and magnitude are in good quantitative agreement with the measurements.

AB - We perform bimodal atomic force microscopy measurements on a Br-doped NaCl (001) surface to investigate the mechanisms behind frequency shift and energy dissipation contrasts. The peculiar pattern of the dissipated energy in the torsional channel, related to frictional processes, is increased at the positions of Br impurities, otherwise indistinguishable from Cl ions in the other measured channels. Our simulations reveal how the energy dissipates by the rearrangement of the tip apex and how the process is ultimately governed by lateral forces. Even the slightest change in lateral forces, induced by the presence of a Br impurity, is enough to trigger the apex reconstruction more often, thus increasing the dissipation contrast; the predicted dissipation pattern and magnitude are in good quantitative agreement with the measurements.

KW - AFM

KW - MD

KW - AFM

KW - MD

KW - AFM

KW - MD

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DO - 10.1103/PhysRevLett.110.203203

M3 - Article

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JO - Physical Review Letters

JF - Physical Review Letters

IS - 20

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ER -

Energy loss triggered by atomic-scale lateral force

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