Coherent dynamics of Floquet-Bloch states in monolayer W S2 reveals fast adiabatic switching

S. K. Earl; M. A. Conway; J. B. Muir; M. Wurdack; E. A. Ostrovskaya; J. O. Tollerud; J. A. Davis

doi:10.1103/PhysRevB.104.L060303

Coherent dynamics of Floquet-Bloch states in monolayer W S2 reveals fast adiabatic switching

S. K. Earl, M. A. Conway, J. B. Muir, M. Wurdack, E. A. Ostrovskaya, J. O. Tollerud, J. A. Davis^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

12 Citations (Scopus)

Abstract

Floquet engineering offers a path to optically controlled materials, but experimental implementations have frequently relied on femtosecond pulses to achieve the high peak fields required to maximize light-matter interactions and obtain a measurable response. The Floquet formalism, however, is based on a continuous, periodic drive. Here we use femtosecond laser pulses to drive the optical Stark effect, a simple realization of Floquet engineering, in monolayer WS2. By monitoring the coherent evolution of the free-induction decay, we show that the system evolves adiabatically, and that the finite duration of the pulses does not introduce any effects beyond Floquet theory. Furthermore, we demonstrate that the induced energy shift follows a linear dependence on instantaneous intensity, even for ultrafast driving fields of fewer than 15 optical cycles.

Original language	English
Article number	L060303
Journal	Physical Review B
Volume	104
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevB.104.L060303
Publication status	Published - 1 Aug 2021

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abstract = "Floquet engineering offers a path to optically controlled materials, but experimental implementations have frequently relied on femtosecond pulses to achieve the high peak fields required to maximize light-matter interactions and obtain a measurable response. The Floquet formalism, however, is based on a continuous, periodic drive. Here we use femtosecond laser pulses to drive the optical Stark effect, a simple realization of Floquet engineering, in monolayer WS2. By monitoring the coherent evolution of the free-induction decay, we show that the system evolves adiabatically, and that the finite duration of the pulses does not introduce any effects beyond Floquet theory. Furthermore, we demonstrate that the induced energy shift follows a linear dependence on instantaneous intensity, even for ultrafast driving fields of fewer than 15 optical cycles.",

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AU - Ostrovskaya, E. A.

AU - Tollerud, J. O.

AU - Davis, J. A.

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AB - Floquet engineering offers a path to optically controlled materials, but experimental implementations have frequently relied on femtosecond pulses to achieve the high peak fields required to maximize light-matter interactions and obtain a measurable response. The Floquet formalism, however, is based on a continuous, periodic drive. Here we use femtosecond laser pulses to drive the optical Stark effect, a simple realization of Floquet engineering, in monolayer WS2. By monitoring the coherent evolution of the free-induction decay, we show that the system evolves adiabatically, and that the finite duration of the pulses does not introduce any effects beyond Floquet theory. Furthermore, we demonstrate that the induced energy shift follows a linear dependence on instantaneous intensity, even for ultrafast driving fields of fewer than 15 optical cycles.

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Coherent dynamics of Floquet-Bloch states in monolayer W S2 reveals fast adiabatic switching

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