Author
Listed:
- Hyo Won Kim
(Device Lab., Samsung Advanced Institute of Technology)
- Wonhee Ko
(Device Lab., Samsung Advanced Institute of Technology)
- JiYeon Ku
(Device Lab., Samsung Advanced Institute of Technology)
- Insu Jeon
(Device Lab., Samsung Advanced Institute of Technology)
- Donggyu Kim
(Korea Advanced Institute of Science and Technology (KAIST))
- Hyeokshin Kwon
(Device Lab., Samsung Advanced Institute of Technology)
- Youngtek Oh
(Device Lab., Samsung Advanced Institute of Technology)
- Seunghwa Ryu
(Korea Advanced Institute of Science and Technology (KAIST))
- Young Kuk
(Seoul National University)
- Sung Woo Hwang
(Device Lab., Samsung Advanced Institute of Technology)
- Hwansoo Suh
(Device Lab., Samsung Advanced Institute of Technology)
Abstract
Phonons, which are collective excitations in a lattice of atoms or molecules, play a major role in determining various physical properties of condensed matter, such as thermal and electrical conductivities. In particular, phonons in graphene interact strongly with electrons; however, unlike in usual metals, these interactions between phonons and massless Dirac fermions appear to mirror the rather complicated physics of those between light and relativistic electrons. Therefore, a fundamental understanding of the underlying physics through systematic studies of phonon interactions and excitations in graphene is crucial for realising graphene-based devices. In this study, we demonstrate that the local phonon properties of graphene can be controlled at the nanoscale by tuning the interaction strength between graphene and an underlying Pt substrate. Using scanning probe methods, we determine that the reduced interaction due to embedded Ar atoms facilitates electron–phonon excitations, further influencing phonon-assisted inelastic electron tunnelling.
Suggested Citation
Hyo Won Kim & Wonhee Ko & JiYeon Ku & Insu Jeon & Donggyu Kim & Hyeokshin Kwon & Youngtek Oh & Seunghwa Ryu & Young Kuk & Sung Woo Hwang & Hwansoo Suh, 2015.
"Nanoscale control of phonon excitations in graphene,"
Nature Communications, Nature, vol. 6(1), pages 1-5, November.
Handle:
RePEc:nat:natcom:v:6:y:2015:i:1:d:10.1038_ncomms8528
DOI: 10.1038/ncomms8528
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