Author
Listed:
- Wenyu Zhao
(University of California, Berkeley)
- Sihan Zhao
(University of California, Berkeley)
- Hongyuan Li
(University of California, Berkeley
University of California, Berkeley
Lawrence Berkeley National Laboratory)
- Sheng Wang
(University of California, Berkeley
Lawrence Berkeley National Laboratory)
- Shaoxin Wang
(University of California, Berkeley)
- M. Iqbal Bakti Utama
(University of California, Berkeley
Lawrence Berkeley National Laboratory
University of California, Berkeley)
- Salman Kahn
(University of California, Berkeley
Lawrence Berkeley National Laboratory)
- Yue Jiang
(University of California, Berkeley
Chinese University of Hong Kong)
- Xiao Xiao
(University of California, Berkeley
Chinese University of Hong Kong)
- SeokJae Yoo
(University of California, Berkeley)
- Kenji Watanabe
(National Institute for Materials Science)
- Takashi Taniguchi
(National Institute for Materials Science)
- Alex Zettl
(University of California, Berkeley
Lawrence Berkeley National Laboratory
Kavli Energy NanoSciences Institute at University of California Berkeley and Lawrence Berkeley National Laboratory)
- Feng Wang
(University of California, Berkeley
Lawrence Berkeley National Laboratory
Kavli Energy NanoSciences Institute at University of California Berkeley and Lawrence Berkeley National Laboratory)
Abstract
Fizeau demonstrated in 1850 that the speed of light can be modified when it is propagating in moving media1. However, such control of the light speed has not been achieved efficiently with a fast-moving electron media by passing an electrical current. Because the strong electromagnetic coupling between the electron and light leads to the collective excitation of plasmon polaritons, it is hypothesized that Fizeau drag in electron flow systems manifests as a plasmonic Doppler effect. Experimental observation of the plasmonic Doppler effect in electronic systems has been challenge because the plasmon propagation speed is much faster than the electron drift velocity in conventional noble metals. Here we report direct observation of Fizeau drag of plasmon polaritons in strongly biased monolayer graphene by exploiting the high electron mobility and the slow plasmon propagation of massless Dirac electrons. The large bias current in graphene creates a fast-drifting Dirac electron medium hosting the plasmon polariton. This results in non-reciprocal plasmon propagation, where plasmons moving with the drifting electron media propagate at an enhanced speed. We measure the Doppler-shifted plasmon wavelength using cryogenic near-field infrared nanoscopy, which directly images the plasmon polariton mode in the biased graphene at low temperature. We observe a plasmon wavelength difference of up to 3.6 per cent between a plasmon moving with and a plasmon moving against the drifting electron media. Our findings on the plasmonic Doppler effect provide opportunities for electrical control of non-reciprocal surface plasmon polaritons in non-equilibrium systems.
Suggested Citation
Wenyu Zhao & Sihan Zhao & Hongyuan Li & Sheng Wang & Shaoxin Wang & M. Iqbal Bakti Utama & Salman Kahn & Yue Jiang & Xiao Xiao & SeokJae Yoo & Kenji Watanabe & Takashi Taniguchi & Alex Zettl & Feng Wa, 2021.
"Efficient Fizeau drag from Dirac electrons in monolayer graphene,"
Nature, Nature, vol. 594(7864), pages 517-521, June.
Handle:
RePEc:nat:nature:v:594:y:2021:i:7864:d:10.1038_s41586-021-03574-4
DOI: 10.1038/s41586-021-03574-4
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