Lightwave control of topological properties in 2D materials for sub-cycle and non-resonant valley manipulation

Modern light generation technology offers extraordinary capabilities for sculpting light pulses, with full control over individual electric field oscillations within each laser cycle 1 – 3 . These capabilities are at the core of lightwave electronics—the dream of ultrafast lightwave control over ele...

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Bibliographic Details
Published in:Nature photonics Vol. 14; no. 12; pp. 728 - 732
Main Authors: Jiménez-Galán, Á., Silva, R. E. F., Smirnova, O., Ivanov, M.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-12-2020
Nature Publishing Group
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Summary:Modern light generation technology offers extraordinary capabilities for sculpting light pulses, with full control over individual electric field oscillations within each laser cycle 1 – 3 . These capabilities are at the core of lightwave electronics—the dream of ultrafast lightwave control over electron dynamics in solids on a sub-cycle timescale, aiming at information processing at petahertz rates 4 – 8 . Here, bringing the frequency-domain concept of topological Floquet systems 9 , 10 to the few-femtosecond time domain, we develop a theoretical method that can be implemented with existing technology, to control the topological properties of two-dimensional materials on few-femtosecond timescales by controlling the sub-cycle structure of non-resonant driving fields. We use this method to propose an all-optical, non-element-specific technique, physically transparent in real space, to coherently write, manipulate and read selective valley excitation using fields carried in a wide range of frequencies and on timescales that are orders of magnitude shorter than the valley lifetime, crucial for the implementation of valleytronic devices 11 , 12 . A method to control the topological properties of two-dimensional (2D) materials on few-femtosecond timescales is proposed. By controlling the sub-cycle structure of non-resonant driving fields, it may be possible to coherently write, manipulate and read selective valley excitation.
ISSN:1749-4885
1749-4893
DOI:10.1038/s41566-020-00717-3