Author
Listed:
- C. P. Schmid
(University of Regensburg)
- L. Weigl
(University of Regensburg)
- P. Grössing
(University of Regensburg)
- V. Junk
(University of Regensburg)
- C. Gorini
(University of Regensburg
Université Paris-Saclay, CEA, CNRS, SPEC)
- S. Schlauderer
(University of Regensburg)
- S. Ito
(Philipps-University of Marburg)
- M. Meierhofer
(University of Regensburg)
- N. Hofmann
(University of Regensburg)
- D. Afanasiev
(University of Regensburg)
- J. Crewse
(University of Regensburg)
- K. A. Kokh
(V.S. Sobolev Institute of Geology and Mineralogy SB RAS
Novosibirsk State University)
- O. E. Tereshchenko
(Novosibirsk State University
A.V. Rzhanov Institute of Semiconductor Physics SB RAS)
- J. Güdde
(Philipps-University of Marburg)
- F. Evers
(University of Regensburg)
- J. Wilhelm
(University of Regensburg)
- K. Richter
(University of Regensburg)
- U. Höfer
(Philipps-University of Marburg)
- R. Huber
(University of Regensburg)
Abstract
When intense lightwaves accelerate electrons through a solid, the emerging high-order harmonic (HH) radiation offers key insights into the material1–11. Sub-optical-cycle dynamics—such as dynamical Bloch oscillations2–5, quasiparticle collisions6,12, valley pseudospin switching13 and heating of Dirac gases10—leave fingerprints in the HH spectra of conventional solids. Topologically non-trivial matter14,15 with invariants that are robust against imperfections has been predicted to support unconventional HH generation16–20. Here we experimentally demonstrate HH generation in a three-dimensional topological insulator—bismuth telluride. The frequency of the terahertz driving field sharply discriminates between HH generation from the bulk and from the topological surface, where the unique combination of long scattering times owing to spin–momentum locking17 and the quasi-relativistic dispersion enables unusually efficient HH generation. Intriguingly, all observed orders can be continuously shifted to arbitrary non-integer multiples of the driving frequency by varying the carrier-envelope phase of the driving field—in line with quantum theory. The anomalous Berry curvature warranted by the non-trivial topology enforces meandering ballistic trajectories of the Dirac fermions, causing a hallmark polarization pattern of the HH emission. Our study provides a platform to explore topology and relativistic quantum physics in strong-field control, and could lead to non-dissipative topological electronics at infrared frequencies.
Suggested Citation
C. P. Schmid & L. Weigl & P. Grössing & V. Junk & C. Gorini & S. Schlauderer & S. Ito & M. Meierhofer & N. Hofmann & D. Afanasiev & J. Crewse & K. A. Kokh & O. E. Tereshchenko & J. Güdde & F. Evers & , 2021.
"Tunable non-integer high-harmonic generation in a topological insulator,"
Nature, Nature, vol. 593(7859), pages 385-390, May.
Handle:
RePEc:nat:nature:v:593:y:2021:i:7859:d:10.1038_s41586-021-03466-7
DOI: 10.1038/s41586-021-03466-7
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Cited by:
- Soonyoung Cha & Minjeong Kim & Youngjae Kim & Shinyoung Choi & Sejong Kang & Hoon Kim & Sangho Yoon & Gunho Moon & Taeho Kim & Ye Won Lee & Gil Young Cho & Moon Jeong Park & Cheol-Joo Kim & B. J. Kim , 2022.
"Gate-tunable quantum pathways of high harmonic generation in graphene,"
Nature Communications, Nature, vol. 13(1), pages 1-10, December.
- Jiaojian Shi & Haowei Xu & Christian Heide & Changan HuangFu & Chenyi Xia & Felipe Quesada & Hongzhi Shen & Tianyi Zhang & Leo Yu & Amalya Johnson & Fang Liu & Enzheng Shi & Liying Jiao & Tony Heinz &, 2023.
"Giant room-temperature nonlinearities in a monolayer Janus topological semiconductor,"
Nature Communications, Nature, vol. 14(1), pages 1-8, December.
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