Magnesium-intercalated graphene on SiC: Highly n-doped air-stable bilayer graphene at extreme displacement fields

Antonija Grubisic-Cabo; Jimmy C. Kotsakidis; Yuefeng Yin; Anton Tadich; Matthew Haldon; Sean Solari; Iolanda Di Bernardo; Kevin M. Daniels; John Riley; Eric Huwald; Mark T. Edmonds; Rachael Myers-Ward; Nikhil V. Medhekar; D. Kurt Gaskill; Michael S. Fuhrer

doi:10.1016/j.apsusc.2020.148612

Magnesium-intercalated graphene on SiC: Highly n-doped air-stable bilayer graphene at extreme displacement fields

Antonija Grubisic-Cabo^*, Jimmy C. Kotsakidis, Yuefeng Yin, Anton Tadich, Matthew Haldon, Sean Solari, Iolanda Di Bernardo, Kevin M. Daniels, John Riley, Eric Huwald, Mark T. Edmonds, Rachael Myers-Ward, Nikhil V. Medhekar, D. Kurt Gaskill, Michael S. Fuhrer^*

^*Corresponding author for this work

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

15 Citations (Scopus)

Abstract

We use angle-resolved photoemission spectroscopy to investigate the electronic structure of bilayer graphene at high n-doping and extreme displacement fields, created by intercalating epitaxial monolayer graphene on silicon carbide with magnesium to form quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide. Angle-resolved photoemission spectroscopy reveals that upon magnesium intercalation, the single massless Dirac band of epitaxial monolayer graphene is transformed into the characteristic massive double-band Dirac spectrum of quasi-freestanding bilayer graphene. Analysis of the spectrum using a simple tight binding model indicates that magnesium intercalation results in an n-type doping of 2.1 x 10(14) cm(-2) and creates an extremely high displacement field of 2.6 V/nm, thus opening a considerable gap of 0.36 eV at the Dirac point. This is further confirmed by density-functional theory calculations for quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide, which show a similar doping level, displacement field and bandgap. Finally, magnesium-intercalated samples are surprisingly robust to ambient conditions; no significant changes in the electronic structure are observed after 30 min exposure to air.

Original language	English
Article number	148612
Number of pages	9
Journal	Applied Surface Science
Volume	541
DOIs	https://doi.org/10.1016/j.apsusc.2020.148612
Publication status	Published - 1-Mar-2021
Externally published	Yes

Keywords

Graphene
Extremely high displacement field
Electronic structure
ARPES
Air exposure
ELECTRONIC-PROPERTIES
EPITAXIAL GRAPHENE
TRANSPARENCY
SUBSTITUTION
ORIGIN
DEVICE
LIMITS
STATE
BAND

Access to Document

10.1016/j.apsusc.2020.148612

Handle.net

Persistent link

Cite this

Grubisic-Cabo, A., Kotsakidis, J. C., Yin, Y., Tadich, A., Haldon, M., Solari, S., Di Bernardo, I., Daniels, K. M., Riley, J., Huwald, E., Edmonds, M. T., Myers-Ward, R., Medhekar, N. V., Gaskill, D. K., & Fuhrer, M. S. (2021). Magnesium-intercalated graphene on SiC: Highly n-doped air-stable bilayer graphene at extreme displacement fields. Applied Surface Science, 541, Article 148612. https://doi.org/10.1016/j.apsusc.2020.148612

@article{70d5594f99ad414c9ae27beba80f061f,

title = "Magnesium-intercalated graphene on SiC: Highly n-doped air-stable bilayer graphene at extreme displacement fields",

abstract = "We use angle-resolved photoemission spectroscopy to investigate the electronic structure of bilayer graphene at high n-doping and extreme displacement fields, created by intercalating epitaxial monolayer graphene on silicon carbide with magnesium to form quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide. Angle-resolved photoemission spectroscopy reveals that upon magnesium intercalation, the single massless Dirac band of epitaxial monolayer graphene is transformed into the characteristic massive double-band Dirac spectrum of quasi-freestanding bilayer graphene. Analysis of the spectrum using a simple tight binding model indicates that magnesium intercalation results in an n-type doping of 2.1 x 10(14) cm(-2) and creates an extremely high displacement field of 2.6 V/nm, thus opening a considerable gap of 0.36 eV at the Dirac point. This is further confirmed by density-functional theory calculations for quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide, which show a similar doping level, displacement field and bandgap. Finally, magnesium-intercalated samples are surprisingly robust to ambient conditions; no significant changes in the electronic structure are observed after 30 min exposure to air.",

keywords = "Graphene, Extremely high displacement field, Electronic structure, ARPES, Air exposure, ELECTRONIC-PROPERTIES, EPITAXIAL GRAPHENE, TRANSPARENCY, SUBSTITUTION, ORIGIN, DEVICE, LIMITS, STATE, BAND",

author = "Antonija Grubisic-Cabo and Kotsakidis, {Jimmy C.} and Yuefeng Yin and Anton Tadich and Matthew Haldon and Sean Solari and {Di Bernardo}, Iolanda and Daniels, {Kevin M.} and John Riley and Eric Huwald and Edmonds, {Mark T.} and Rachael Myers-Ward and Medhekar, {Nikhil V.} and Gaskill, {D. Kurt} and Fuhrer, {Michael S.}",

year = "2021",

month = mar,

day = "1",

doi = "10.1016/j.apsusc.2020.148612",

language = "English",

volume = "541",

journal = "Applied Surface Science",

issn = "0169-4332",

publisher = "ELSEVIER SCIENCE BV",

}

Grubisic-Cabo, A, Kotsakidis, JC, Yin, Y, Tadich, A, Haldon, M, Solari, S, Di Bernardo, I, Daniels, KM, Riley, J, Huwald, E, Edmonds, MT, Myers-Ward, R, Medhekar, NV, Gaskill, DK & Fuhrer, MS 2021, 'Magnesium-intercalated graphene on SiC: Highly n-doped air-stable bilayer graphene at extreme displacement fields', Applied Surface Science, vol. 541, 148612. https://doi.org/10.1016/j.apsusc.2020.148612

TY - JOUR

T1 - Magnesium-intercalated graphene on SiC

T2 - Highly n-doped air-stable bilayer graphene at extreme displacement fields

AU - Grubisic-Cabo, Antonija

AU - Kotsakidis, Jimmy C.

AU - Yin, Yuefeng

AU - Tadich, Anton

AU - Haldon, Matthew

AU - Solari, Sean

AU - Di Bernardo, Iolanda

AU - Daniels, Kevin M.

AU - Riley, John

AU - Huwald, Eric

AU - Edmonds, Mark T.

AU - Myers-Ward, Rachael

AU - Medhekar, Nikhil V.

AU - Gaskill, D. Kurt

AU - Fuhrer, Michael S.

PY - 2021/3/1

Y1 - 2021/3/1

N2 - We use angle-resolved photoemission spectroscopy to investigate the electronic structure of bilayer graphene at high n-doping and extreme displacement fields, created by intercalating epitaxial monolayer graphene on silicon carbide with magnesium to form quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide. Angle-resolved photoemission spectroscopy reveals that upon magnesium intercalation, the single massless Dirac band of epitaxial monolayer graphene is transformed into the characteristic massive double-band Dirac spectrum of quasi-freestanding bilayer graphene. Analysis of the spectrum using a simple tight binding model indicates that magnesium intercalation results in an n-type doping of 2.1 x 10(14) cm(-2) and creates an extremely high displacement field of 2.6 V/nm, thus opening a considerable gap of 0.36 eV at the Dirac point. This is further confirmed by density-functional theory calculations for quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide, which show a similar doping level, displacement field and bandgap. Finally, magnesium-intercalated samples are surprisingly robust to ambient conditions; no significant changes in the electronic structure are observed after 30 min exposure to air.

AB - We use angle-resolved photoemission spectroscopy to investigate the electronic structure of bilayer graphene at high n-doping and extreme displacement fields, created by intercalating epitaxial monolayer graphene on silicon carbide with magnesium to form quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide. Angle-resolved photoemission spectroscopy reveals that upon magnesium intercalation, the single massless Dirac band of epitaxial monolayer graphene is transformed into the characteristic massive double-band Dirac spectrum of quasi-freestanding bilayer graphene. Analysis of the spectrum using a simple tight binding model indicates that magnesium intercalation results in an n-type doping of 2.1 x 10(14) cm(-2) and creates an extremely high displacement field of 2.6 V/nm, thus opening a considerable gap of 0.36 eV at the Dirac point. This is further confirmed by density-functional theory calculations for quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide, which show a similar doping level, displacement field and bandgap. Finally, magnesium-intercalated samples are surprisingly robust to ambient conditions; no significant changes in the electronic structure are observed after 30 min exposure to air.

KW - Graphene

KW - Extremely high displacement field

KW - Electronic structure

KW - ARPES

KW - Air exposure

KW - ELECTRONIC-PROPERTIES

KW - EPITAXIAL GRAPHENE

KW - TRANSPARENCY

KW - SUBSTITUTION

KW - ORIGIN

KW - DEVICE

KW - LIMITS

KW - STATE

KW - BAND

U2 - 10.1016/j.apsusc.2020.148612

DO - 10.1016/j.apsusc.2020.148612

M3 - Article

SN - 0169-4332

VL - 541

JO - Applied Surface Science

JF - Applied Surface Science

M1 - 148612

ER -

Magnesium-intercalated graphene on SiC: Highly n-doped air-stable bilayer graphene at extreme displacement fields

Abstract

Keywords

Access to Document

Handle.net

Fingerprint

Cite this