Author
Listed:
- Shaohua Zhou
(Tsinghua University
Tsinghua University)
- Changhua Bao
(Tsinghua University
Tsinghua University)
- Benshu Fan
(Tsinghua University
Tsinghua University)
- Hui Zhou
(Institute of Physics, Chinese Academy of Sciences)
- Qixuan Gao
(Tsinghua University
Tsinghua University)
- Haoyuan Zhong
(Tsinghua University
Tsinghua University)
- Tianyun Lin
(Tsinghua University
Tsinghua University)
- Hang Liu
(Institute of Physics, Chinese Academy of Sciences
Songshan Lake Materials Laboratory)
- Pu Yu
(Tsinghua University
Tsinghua University
Frontier Science Center for Quantum Information)
- Peizhe Tang
(Beihang University
Max Planck Institute for the Structure and Dynamics of Matter, Center for Free-Electron Laser Science)
- Sheng Meng
(Institute of Physics, Chinese Academy of Sciences
Songshan Lake Materials Laboratory)
- Wenhui Duan
(Tsinghua University
Tsinghua University
Frontier Science Center for Quantum Information)
- Shuyun Zhou
(Tsinghua University
Tsinghua University
Frontier Science Center for Quantum Information)
Abstract
Time-periodic light field has emerged as a control knob for manipulating quantum states in solid-state materials1–3, cold atoms4 and photonic systems5 through hybridization with photon-dressed Floquet states6 in the strong-coupling limit, dubbed Floquet engineering. Such interaction leads to tailored properties of quantum materials7–11, for example, modifications of the topological properties of Dirac materials12,13 and modulation of the optical response14–16. Despite extensive research interests over the past decade3,8,17–20, there is no experimental evidence of momentum-resolved Floquet band engineering of semiconductors, which is a crucial step to extend Floquet engineering to a wide range of solid-state materials. Here, on the basis of time and angle-resolved photoemission spectroscopy measurements, we report experimental signatures of Floquet band engineering in a model semiconductor, black phosphorus. On near-resonance pumping at a photon energy of 340–440 meV, a strong band renormalization is observed near the band edges. In particular, light-induced dynamical gap opening is resolved at the resonance points, which emerges simultaneously with the Floquet sidebands. Moreover, the band renormalization shows a strong selection rule favouring pump polarization along the armchair direction, suggesting pseudospin selectivity for the Floquetband engineering as enforced by the lattice symmetry. Our work demonstrates pseudospin-selective Floquet band engineering in black phosphorus and provides important guiding principles for Floquet engineering of semiconductors.
Suggested Citation
Shaohua Zhou & Changhua Bao & Benshu Fan & Hui Zhou & Qixuan Gao & Haoyuan Zhong & Tianyun Lin & Hang Liu & Pu Yu & Peizhe Tang & Sheng Meng & Wenhui Duan & Shuyun Zhou, 2023.
"Pseudospin-selective Floquet band engineering in black phosphorus,"
Nature, Nature, vol. 614(7946), pages 75-80, February.
Handle:
RePEc:nat:nature:v:614:y:2023:i:7946:d:10.1038_s41586-022-05610-3
DOI: 10.1038/s41586-022-05610-3
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Cited by:
- E. Wang & J. D. Adelinia & M. Chavez-Cervantes & T. Matsuyama & M. Fechner & M. Buzzi & G. Meier & A. Cavalleri, 2023.
"Superconducting nonlinear transport in optically driven high-temperature K3C60,"
Nature Communications, Nature, vol. 14(1), pages 1-6, December.
- Rao Fu & Yusong Qu & Mengfei Xue & Xinghui Liu & Shengyao Chen & Yongqian Zhao & Runkun Chen & Boxuan Li & Hongming Weng & Qian Liu & Qing Dai & Jianing Chen, 2024.
"Manipulating hyperbolic transient plasmons in a layered semiconductor,"
Nature Communications, Nature, vol. 15(1), pages 1-8, December.
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