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7 results on '"Martin Mootz"'

1. Chirality manipulation of ultrafast phase switches in a correlated CDW-Weyl semimetal

Author

Bing Cheng, Di Cheng, Tao Jiang, Wei Xia, Boqun Song, Martin Mootz, Liang Luo, Ilias E. Perakis, Yongxin Yao, Yanfeng Guo, and Jigang Wang

Subjects
Science
Abstract

Abstract Light engineering of correlated states in topological materials provides a new avenue of achieving exotic topological phases inaccessible by conventional tuning methods. Here we demonstrate a light control of correlation gaps in a model charge-density-wave (CDW) and polaron insulator (TaSe4)2I recently predicted to be an axion insulator. Our ultrafast terahertz photocurrent spectroscopy reveals a two-step, non-thermal melting of polarons and electronic CDW gap via the fluence dependence of a longitudinal circular photogalvanic current. This helicity-dependent photocurrent reveals continuous ultrafast phase switches from the polaronic state to the CDW (axion) phase, and finally to a hidden Weyl phase as the pump fluence increases. Additional distinctive attributes aligning with the light-induced switches include: the mode-selective coupling of coherent phonons to the polaron and CDW modulation, and the emergence of a non-thermal chiral photocurrent above the pump threshold of CDW-related phonons. The demonstrated ultrafast chirality control of correlated topological states here holds large potentials for realizing axion electrodynamics and advancing quantum-computing applications.

Published
2024
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2. Room temperature persisting surface charge carriers driven by intense terahertz electric fields in a topological insulator Bi2Se3

Author

Liang Luo, Di Cheng, Chuankun Huang, Xu Yang, Chirag Vaswani, Martin Mootz, Yongxin Yao, Xinyu Liu, Margaret Dobrowolska, Jacek K. Furdyna, Ilias E. Perakis, and Jigang Wang

Subjects
Biotechnology, TP248.13-248.65, Physics, QC1-999
Abstract

Topologically protected surface current is highly promising for next-generation low-dissipation and disorder-tolerant quantum electronics and computing. Yet, electric transport from the co-existing bulk state dominates the responses of the Dirac surface state, especially at elevated temperatures relevant to technological applications. Here, we present an approach that convincingly showcases the generation, disentanglement, and precise control of enduring surface charge carriers on a topological insulator, Bi2Se3, with high bulk conductivity, all achieved at room temperature. By using pump–probe modulation spectroscopy under ultrabroadband driving tunable from 4 meV to 1.55 eV, we show the terahertz (THz) field-induced surface carriers by discovering their initial temporal responses dominant over high density trivial bulk carriers. Strikingly, the response of the induced surface carrier responses persists for more than ∼5 ps and is enhanced by reducing pump photon energy. The dynamics and lifetime of the distinct surface response manifest themselves as the enhanced THz pump-induced THz transmission, which directly correlates with the transient negative THz conductivity. Increasing the THz driving field reduces the induced surface carrier lifetime and identifies, particularly, an optimal pump field of Es ∼ 224 kV cm−1 for generating the dominant surface response relative to the bulk. This surface carrier dominant regime is suppressed by a joint effect of enhanced surface-bulk scattering and a more rapid saturation of surface excitation compared to the bulk that sets in above Es. The controllability of room temperature topologically surface carriers through pump photon energy offer compelling possibilities for extending this approach to other topological complex materials.

Published
2023
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3. Visualization and quantum control of light-accelerated condensates by terahertz multi-dimensional coherent spectroscopy

Author

Martin Mootz, Liang Luo, Jigang Wang, and llias E. Perakis

Subjects
Astrophysics, QB460-466, Physics, QC1-999
Abstract

At ultrafast time scales, for example, through light-matter interactions, exotic phases in quantum systems can be realised but identifying and characterising these phases from other excitations is complex. Here, the authors theoretically demonstrate how to identify the experimental signatures of a non-equilibrium superconducting state using multi-dimensional coherent spectroscopy in the terahertz regime.

Published
2022
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4. Study of Elastic and Structural Properties of BaFe2As2 Ultrathin Film Using Picosecond Ultrasonics

Author

Di Cheng, Boqun Song, Jong-Hoon Kang, Chris Sundahl, Anthony L. Edgeton, Liang Luo, Joong-Mok Park, Yesusa G. Collantes, Eric E. Hellstrom, Martin Mootz, Ilias E. Perakis, Chang-Beom Eom, and Jigang Wang

Subjects
ultrathin film, BaFe2As2, intrinsic strain, longitudinal acoustic phonon, through-thickness elastic stiffness coefficient (C33), Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

We obtain the through-thickness elastic stiffness coefficient (C33) in nominal 9 nm and 60 nm BaFe2As2 (Ba-122) thin films by using picosecond ultrasonics. Particularly, we reveal the increase in elastic stiffness as film thickness decreases from bulk value down to 9 nm, which we attribute to the increase in intrinsic strain near the film-substrate interface. Our density functional theory (DFT) calculations reproduce the observed acoustic oscillation frequencies well. In addition, temperature dependence of longitudinal acoustic (LA) phonon mode frequency for 9 nm Ba-122 thin film is reported. The frequency change is attributed to the change in Ba-122 orthorhombicity (a−b)/(a+b). This conclusion can be corroborated by our previous ultrafast ellipticity measurements in 9 nm Ba-122 thin film, which exhibit strong temperature dependence and indicate the structural phase transition temperature Ts.

Published
2023
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5. Room temperature persisting surface current driven by intense terahertz electric fields in a topological Insulator

Author

Jigang Wang, L Luo, D Cheng, X Yang, Chirag Vaswani, Martin Mootz, Yong-Xin Yao, Ilias Perakis, Xinyu Liu, Margret Dobrowolska, J Frudyna, and C Juang

Abstract

Topologically-protected surface current is highly promising for next-generation low-dissipation and disorder-tolerant electronics and computing. Yet, electric transport from co-existing bulk state dominates responses of Dirac surface state, especially at the elevated temperatures relevant for technological applications. Here, we demonstrate a compelling scheme to generate, disentangle, and control long-lasting surface transport at room temperature in a model topological insulator Bi2Se3. By using pump-probe modulation spectroscopy under ultrabroadband driving tunable from 4 meV to 1.55 eV, we underpin the terahertz (THz) field-induced surface currents by discovering their initial temporal responses dominant over high density trivial bulk carriers. Strikingly, these surface currents persist more than a longlived ~5 ps and amplify by reducing pump photon energy. The dynamics and lifetime of the distinct surface current manifest themselves as the pump-induced THz transmission, which directly correlates with the transient negative THz conductivity. Increasing THz driving field reduces the surface current lifetime and identifies, particularly, an optimal pump field Es~224 kV/cm for generating the dominant surface transport relative to the bulk. This surface current dominant regime is suppressed by a joint effect of enhanced surface-bulk scattering and faster surface carrier saturation than the bulk that sets in above Es. The room temperature topological current controllable by pump photon energy shown provides compelling extensions to other topological complex materials including chiral semimetals, superconductors, and magnets.

Published
2022

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