Lightwave valleytronics in a monolayer of tungsten diselenide

Langer, F. and Schmid, C. P. and Schlauderer, S. and Gmitra, M. and Fabian, J. and Nagler, P. and Schueller, C. and Korn, T. and Hawkins, P. G. and Steiner, J. T. and Huttner, U. and Koch, S. W. and Kira, M. and Huber, R. (2018) Lightwave valleytronics in a monolayer of tungsten diselenide. NATURE, 557 (7703). 76-+. ISSN 0028-0836, 1476-4687

Full text not available from this repository. (Request a copy)

Abstract

As conventional electronics approaches its limits(1), nanoscience has urgently sought methods of fast control of electrons at the fundamental quantum level(2). Lightwave electronics(3)-the foundation of attosecond science(4)-uses the oscillating carrier wave of intense light pulses to control the translational motion of the electron's charge faster than a single cycle of light(5-15). Despite being particularly promising information carriers, the internal quantum attributes of spin(16) and valley pseudospin(17-21) have not been switchable on the subcycle scale. Here we demonstrate lightwave-driven changes of the valley pseudospin and introduce distinct signatures in the optical readout. Photogenerated electron-hole pairs in a monolayer of tungsten diselenide are accelerated and collided by a strong lightwave. The emergence of high-odd-order sidebands and anomalous changes in their polarization direction directly attest to the ultrafast pseudospin dynamics. Quantitative computations combining density functional theory with a non-perturbative quantum many-body approach assign the polarization of the sidebands to a lightwave-induced change of the valley pseudospin and confirm that the process is coherent and adiabatic. Our work opens the door to systematic valleytronic logic at optical clock rates.

Item Type: Article
Uncontrolled Keywords: HIGH-HARMONIC GENERATION; QUANTUM; GRAPHENE; WSE2; COMPUTATION; METROLOGY; ELECTRONS; FUTURE; MOS2; SPIN;
Subjects: 500 Science > 530 Physics
Divisions: Physics > Institute of Experimental and Applied Physics > Chair Professor Huber > Group Rupert Huber
Depositing User: Dr. Gernot Deinzer
Date Deposited: 04 Mar 2020 13:47
Last Modified: 04 Mar 2020 13:47
URI: https://pred.uni-regensburg.de/id/eprint/14591

Actions (login required)

View Item View Item
pred is powered by EPrints 3.4 which is developed by the School of Electronics and Computer Science at the University of Southampton. More information and software credits.