Dual harmonic Kelvin probe force microscopy at the graphene-liquid interface

Liam Collins; Jason I. Kilpatrick; Ivan V. Vlassiouk; Alexander Tselev; Stefan A.L. Weber; Stephen Jesse; Sergei V. Kalinin; Brian J. Rodriguez

doi:10.1063/1.4870074

Dual harmonic Kelvin probe force microscopy at the graphene-liquid interface

Liam Collins, Jason I. Kilpatrick, Ivan V. Vlassiouk, Alexander Tselev, Stefan A.L. Weber, Stephen Jesse, Sergei V. Kalinin, Brian J. Rodriguez

Research output: Contribution to journal › Article › peer-review

51 Scopus citations

Abstract

Kelvin probe force microscopy (KPFM) is a powerful technique for the determination of the contact potential difference (CPD) between an atomic force microscope tip and a sample under ambient and vacuum conditions. However, for many energy storage and conversion systems, including graphene-based electrochemical capacitors, understanding electrochemical phenomena at the solid-liquid interface is paramount. Despite the vast potential to provide fundamental insight for energy storage materials at the nanoscale, KPFM has found limited applicability in liquid environments to date. Here, using dual harmonic (DH)-KPFM, we demonstrate CPD imaging of graphene in liquid. We find good agreement with measurements performed in air, highlighting the potential of DH-KPFM to probe electrochemistry at the graphene-liquid interface.

Original language	English
Article number	133103
Journal	Applied Physics Letters
Volume	104
Issue number	13
DOIs	https://doi.org/10.1063/1.4870074
State	Published - Mar 31 2014

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title = "Dual harmonic Kelvin probe force microscopy at the graphene-liquid interface",

abstract = "Kelvin probe force microscopy (KPFM) is a powerful technique for the determination of the contact potential difference (CPD) between an atomic force microscope tip and a sample under ambient and vacuum conditions. However, for many energy storage and conversion systems, including graphene-based electrochemical capacitors, understanding electrochemical phenomena at the solid-liquid interface is paramount. Despite the vast potential to provide fundamental insight for energy storage materials at the nanoscale, KPFM has found limited applicability in liquid environments to date. Here, using dual harmonic (DH)-KPFM, we demonstrate CPD imaging of graphene in liquid. We find good agreement with measurements performed in air, highlighting the potential of DH-KPFM to probe electrochemistry at the graphene-liquid interface.",

author = "Liam Collins and Kilpatrick, \{Jason I.\} and Vlassiouk, \{Ivan V.\} and Alexander Tselev and Weber, \{Stefan A.L.\} and Stephen Jesse and Kalinin, \{Sergei V.\} and Rodriguez, \{Brian J.\}",

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doi = "10.1063/1.4870074",

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AU - Collins, Liam

AU - Kilpatrick, Jason I.

AU - Vlassiouk, Ivan V.

AU - Tselev, Alexander

AU - Weber, Stefan A.L.

AU - Jesse, Stephen

AU - Kalinin, Sergei V.

AU - Rodriguez, Brian J.

PY - 2014/3/31

Y1 - 2014/3/31

N2 - Kelvin probe force microscopy (KPFM) is a powerful technique for the determination of the contact potential difference (CPD) between an atomic force microscope tip and a sample under ambient and vacuum conditions. However, for many energy storage and conversion systems, including graphene-based electrochemical capacitors, understanding electrochemical phenomena at the solid-liquid interface is paramount. Despite the vast potential to provide fundamental insight for energy storage materials at the nanoscale, KPFM has found limited applicability in liquid environments to date. Here, using dual harmonic (DH)-KPFM, we demonstrate CPD imaging of graphene in liquid. We find good agreement with measurements performed in air, highlighting the potential of DH-KPFM to probe electrochemistry at the graphene-liquid interface.

AB - Kelvin probe force microscopy (KPFM) is a powerful technique for the determination of the contact potential difference (CPD) between an atomic force microscope tip and a sample under ambient and vacuum conditions. However, for many energy storage and conversion systems, including graphene-based electrochemical capacitors, understanding electrochemical phenomena at the solid-liquid interface is paramount. Despite the vast potential to provide fundamental insight for energy storage materials at the nanoscale, KPFM has found limited applicability in liquid environments to date. Here, using dual harmonic (DH)-KPFM, we demonstrate CPD imaging of graphene in liquid. We find good agreement with measurements performed in air, highlighting the potential of DH-KPFM to probe electrochemistry at the graphene-liquid interface.

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VL - 104

JO - Applied Physics Letters

JF - Applied Physics Letters

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Dual harmonic Kelvin probe force microscopy at the graphene-liquid interface

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