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Spectroscopic Evidence of Ultrafast Topological Phase Transition by Light-Driven Strain

Title
Spectroscopic Evidence of Ultrafast Topological Phase Transition by Light-Driven Strain
Author(s)
Park, Tae GwanBaek, SeungilPark, JunhoShin, Eui-CheolNa, Hong RyeolOh, Eon-TaekChun, Seung-HyunKim, Yong-HyunLee, SunghunRotermund, Fabian
Issued Date
2024-10
Citation
ACS Nano, v.18, no.45, pp.30966 - 30977
Type
Article
Author Keywords
topological insulatorslight-induced phase transitionTHz spectroscopycoherent phononsinterlayer vibrationsultrafast spectroscopy
Keywords
ELASTIC PROPERTIESINSULATOR BI2SE3CONDUCTIVITYGRAPHENE
ISSN
1936-0851
Abstract
Enabling reversible control over the topological invariants, transitioning them from nontrivial to trivial states, has fundamental implications for quantum information processing and spintronics. It offers a promising avenue for establishing an efficient on/off switch mechanism for robust and dissipationless spin-currents. While mechanical strain has traditionally been advantageous for such manipulation of topological invariants, it often comes with the drawback of in-plane fractures, rendering it unsuitable for high-speed, time-dependent operations. This study employs ultrafast optical and THz spectroscopy to explore topological phase transitions induced by light-driven strain in Bi2Se3. Bi2Se3 requires substantial strain for Z2 switching. Our observations provide experimental evidence of ultrafast switching behavior, demonstrating a transition from a topological insulator with spin-momentum-locked surfaces to hybridized states and normal insulating phases under ambient conditions. Notably, applying light-induced strong out-of-plane strain effectively suppresses surface-bulk coupling, facilitating the differentiation of surface and bulk conductance even at room temperature─significantly surpassing the Debye temperature. We expect various time-dependent sequences of transient hybridization and manipulation of topological invariant through photoexcitation intensity adjustments. The sudden surface and bulk transport alterations near the transition point enable coherent conductance modulation at hypersound frequencies. Our findings on the potential of light-triggered ultrafast switching of topological invariants hold promise for high-speed topological switching and its related applications. © 2024 American Chemical Society.
URI
http://hdl.handle.net/20.500.11750/57202
DOI
10.1021/acsnano.4c06253
Publisher
American Chemical Society
Related Researcher
  • 이성훈 Lee, Sunghun
  • Research Interests Nanomaterials; 나노물질; Nanostructures; 나노구조; Topological matters; 위상물질; 2D materials; 2차원 물질; Strain sensor; 스트레인 센서
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Division of Nanotechnology 1. Journal Articles

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