Graphene phonons are measured as a function of electron doping via the
addition of potassium adatoms. In the low doping regime, the in-plane carbon
G-peak hardens and narrows with increasing doping, analogous to the trend seen
in graphene doped via the field-effect. At high dopings, beyond those
accessible by the field-effect, the G-peak strongly softens and broadens. This
is interpreted as a dynamic, non-adiabatic renormalization of the phonon
self-energy. At dopings between the light and heavily doped regimes, we find a
robust inhomogeneous phase where the potassium coverage is segregated into
regions of high and low density. The phonon energies, linewidths and tunability
are remarkably similar for 1-4 layer graphene, but significantly different to
doped bulk graphite.Comment: Accepted in Phys. Rev. B as a Rapid Communication. 5 pages, 3
  figures, revised text with additional dat

Dean, M. P. M.

Howard, C. A.

Howard, Christopher

Withers, F.

English

arXiv

C. A. Howard

M. P. M. Dean

F. Withers

Crossref

Physical Review B

Phonons in potassium-doped graphene: The effects of electron-phonon interactions, dimensionality, and adatom ordering

Royal Holloway - Pure

Graphene phonons are measured as a function of electron doping via the addition of potassium adatoms. In the low doping regime, the in-plane carbon G peak hardens and narrows with increasing doping, analogous to the trend seen in graphene doped via the field effect. At high dopings, beyond those accessible by the field effect, the G peak strongly softens and broadens. This is interpreted as a dynamic, nonadiabatic renormalization of the phonon self-energy. At dopings between the light and heavily doped regimes, we find a robust inhomogeneous phase where the potassium coverage is segregated into regions of high and low density. The phonon energies, linewidths, and tunability are notably very similar for one- to four-layer potassium-doped graphene, but significantly different to bulk potassium-doped graphite

Royal Holloway Research Online

This is the author accepted manuscript. The final version is available from the publisher via the DOI in this record.Graphene phonons are measured as a function of electron doping via the addition of potassium adatoms. In the low doping regime, the in-plane carbon G-peak hardens and narrows with increasing doping, analogous to the trend seen in graphene doped via the field-effect. At high dopings, beyond those accessible by the field-effect, the G-peak strongly softens and broadens. This is interpreted as a dynamic, non-adiabatic renormalization of the phonon self-energy. At dopings between the light and heavily doped regimes, we find a robust inhomogeneous phase where the potassium coverage is segregated into regions of high and low density. The phonon energies, linewidths and tunability are remarkably similar for 1-4 layer graphene, but significantly different to doped bulk graphite.We thank the EPSRC for funding, Felix Fernandez-Alonso,
Andrew Walters, and Mark Ellerby for fruitful discussions, and
Steve Firth for technical assistance. The work at Brookhaven
is supported by the US DOE under Contract No. DEAC02-
98CH10886 and by the Center for Emergent Superconductivity,
an Energy Frontier Research Center funded by the US
DOE, Office of Basic Energy Sciences

Howard, CA

Dean, MPM

Withers, F

Open Research Exeter

Phonons in potassium doped graphene: the effects of electron-phonon interactions, dimensionality and ad-atom ordering

Phonons in potassium doped graphene: the effects of electron-phonon
  interactions, dimensionality and ad-atom ordering

Phonons in potassium doped graphene: the effects of electron-phonon interactions, dimensionality and ad-atom ordering

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Royal Holloway - Pure

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Royal Holloway Research Online

Royal Holloway Research Online

Royal Holloway Research Online

Royal Holloway Research Online

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