Surface potential distribution of multilayer graphene using Kelvin probe and electric-field force microscopies

R. Vidyasagar; B. Camargo; K. Romanyuk; A. L. Kholkin

doi:10.1080/00150193.2017.1289583

Surface potential distribution of multilayer graphene using Kelvin probe and electric-field force microscopies

R. Vidyasagar
, B. Camargo
, K. Romanyuk
, A. L. Kholkin^*

^*Šī darba korespondējošais autors

University of Aveiro
Leipzig University
Ural Federal University

Zinātniskās darbības rezultāts: Devums žurnālam › Zinātniskais raksts (žurnālā) › koleģiāli recenzēts

6 Atsauces (Scopus)

Kopsavilkums

Surface properties of multilayer graphene (MLG) were studied by Kelvin Probe and Electric-field Force Microscopies (KPFM and EFM). Using KPFM, we observed an increase in the work function of MLG with increasing thickness. This is attributed to the surface π-electrons of p_z orbitals shifting the Fermi level away from the Dirac point. EFM measurements indicate that the EFM phase increases with DC electric fields (−5 V ≤ V ≤ 5 V) applied to the probe. The parabolic phase-shift dependence is pertaining to the electrostatic interaction produced at the tip-MLG interface. These results provide future directions in band-gap engineering of graphene-based devices.

Oriģinālvaloda	Angļu
Lapas (no-līdz)	115-123
Lapu skaits	9
Žurnāls	Ferroelectrics
Sējums	508
Izdevuma numurs	1
DOIs	https://doi.org/10.1080/00150193.2017.1289583
Publikācijas statuss	Publicēts - 17 febr. 2017
Ārēji publicēts	Jā

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title = "Surface potential distribution of multilayer graphene using Kelvin probe and electric-field force microscopies",

abstract = "Surface properties of multilayer graphene (MLG) were studied by Kelvin Probe and Electric-field Force Microscopies (KPFM and EFM). Using KPFM, we observed an increase in the work function of MLG with increasing thickness. This is attributed to the surface π-electrons of pz orbitals shifting the Fermi level away from the Dirac point. EFM measurements indicate that the EFM phase increases with DC electric fields (−5 V ≤ V ≤ 5 V) applied to the probe. The parabolic phase-shift dependence is pertaining to the electrostatic interaction produced at the tip-MLG interface. These results provide future directions in band-gap engineering of graphene-based devices.",

keywords = "EFM, Graphene, KPFM, potential",

author = "R. Vidyasagar and B. Camargo and K. Romanyuk and Kholkin, \{A. L.\}",

note = "Publisher Copyright: {\textcopyright} 2017 Taylor \& Francis Group, LLC.",

year = "2017",

month = feb,

day = "17",

doi = "10.1080/00150193.2017.1289583",

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T1 - Surface potential distribution of multilayer graphene using Kelvin probe and electric-field force microscopies

AU - Vidyasagar, R.

AU - Camargo, B.

AU - Romanyuk, K.

AU - Kholkin, A. L.

PY - 2017/2/17

Y1 - 2017/2/17

N2 - Surface properties of multilayer graphene (MLG) were studied by Kelvin Probe and Electric-field Force Microscopies (KPFM and EFM). Using KPFM, we observed an increase in the work function of MLG with increasing thickness. This is attributed to the surface π-electrons of pz orbitals shifting the Fermi level away from the Dirac point. EFM measurements indicate that the EFM phase increases with DC electric fields (−5 V ≤ V ≤ 5 V) applied to the probe. The parabolic phase-shift dependence is pertaining to the electrostatic interaction produced at the tip-MLG interface. These results provide future directions in band-gap engineering of graphene-based devices.

AB - Surface properties of multilayer graphene (MLG) were studied by Kelvin Probe and Electric-field Force Microscopies (KPFM and EFM). Using KPFM, we observed an increase in the work function of MLG with increasing thickness. This is attributed to the surface π-electrons of pz orbitals shifting the Fermi level away from the Dirac point. EFM measurements indicate that the EFM phase increases with DC electric fields (−5 V ≤ V ≤ 5 V) applied to the probe. The parabolic phase-shift dependence is pertaining to the electrostatic interaction produced at the tip-MLG interface. These results provide future directions in band-gap engineering of graphene-based devices.

KW - EFM

KW - Graphene

KW - KPFM

KW - potential

UR - https://www.scopus.com/pages/publications/85017594925

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DO - 10.1080/00150193.2017.1289583

M3 - Article

AN - SCOPUS:85017594925

SN - 0015-0193

VL - 508

SP - 115

EP - 123

JO - Ferroelectrics

JF - Ferroelectrics

IS - 1

ER -

Surface potential distribution of multilayer graphene using Kelvin probe and electric-field force microscopies

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