Non-reciprocal band structures in an exciton–polariton Floquet optical lattice

Yago del Valle Inclan Redondo; Xingran Xu; Timothy C.H. Liew; Elena A. Ostrovskaya; Alexander Stegmaier; Ronny Thomale; Christian Schneider; Siddhartha Dam; Sebastian Klembt; Sven Höfling; Seigo Tarucha; Michael D. Fraser

doi:10.1038/s41566-024-01424-z

Non-reciprocal band structures in an exciton–polariton Floquet optical lattice

Yago del Valle Inclan Redondo^*, Xingran Xu, Timothy C.H. Liew, Elena A. Ostrovskaya, Alexander Stegmaier, Ronny Thomale, Christian Schneider, Siddhartha Dam, Sebastian Klembt, Sven Höfling, Seigo Tarucha, Michael D. Fraser^*

^*Corresponding author for this work

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

1 Citation (Scopus)

Abstract

Periodic temporal modulation of Hamiltonians can induce geometrical and topological phenomena in the dynamics of quantum states. Using the interference between two lasers, we demonstrate an off-resonant optical lattice for a polariton condensate with controllable potential depths and nearest-neighbour coupling strength. Temporal modulation is introduced via a gigahertz frequency detuning between pump lasers, creating a polariton ‘conveyor belt’. The breaking of time-reversal symmetry causes band structures to become non-reciprocal and acquire a universal tilt given by Planck’s constant and the frequency of modulation (hΔf). The non-reciprocal tilting is connected to the non-trivial topology of the Floquet–Bloch bands, which have a finite Chern number. Detailed characterization of the lattice potential depth and its dynamics highlights the role of high-energy carriers in the formation of optical potential landscapes for polaritons, demonstrating the possibility of modulation faster than the polariton lifetime and opening a pathway towards Floquet engineering in polariton condensates.

Original language	English
Pages (from-to)	548-553
Number of pages	5
Journal	Nature Photonics
Volume	18
DOIs	https://doi.org/10.1038/s41566-024-01424-z
Publication status	Published - 2024

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title = "Non-reciprocal band structures in an exciton–polariton Floquet optical lattice",

abstract = "Periodic temporal modulation of Hamiltonians can induce geometrical and topological phenomena in the dynamics of quantum states. Using the interference between two lasers, we demonstrate an off-resonant optical lattice for a polariton condensate with controllable potential depths and nearest-neighbour coupling strength. Temporal modulation is introduced via a gigahertz frequency detuning between pump lasers, creating a polariton {\textquoteleft}conveyor belt{\textquoteright}. The breaking of time-reversal symmetry causes band structures to become non-reciprocal and acquire a universal tilt given by Planck{\textquoteright}s constant and the frequency of modulation (hΔf). The non-reciprocal tilting is connected to the non-trivial topology of the Floquet–Bloch bands, which have a finite Chern number. Detailed characterization of the lattice potential depth and its dynamics highlights the role of high-energy carriers in the formation of optical potential landscapes for polaritons, demonstrating the possibility of modulation faster than the polariton lifetime and opening a pathway towards Floquet engineering in polariton condensates.",

author = "{del Valle Inclan Redondo}, Yago and Xingran Xu and Liew, {Timothy C.H.} and Ostrovskaya, {Elena A.} and Alexander Stegmaier and Ronny Thomale and Christian Schneider and Siddhartha Dam and Sebastian Klembt and Sven H{\"o}fling and Seigo Tarucha and Fraser, {Michael D.}",

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year = "2024",

doi = "10.1038/s41566-024-01424-z",

language = "English",

volume = "18",

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T1 - Non-reciprocal band structures in an exciton–polariton Floquet optical lattice

AU - del Valle Inclan Redondo, Yago

AU - Xu, Xingran

AU - Liew, Timothy C.H.

AU - Ostrovskaya, Elena A.

AU - Stegmaier, Alexander

AU - Thomale, Ronny

AU - Schneider, Christian

AU - Dam, Siddhartha

AU - Klembt, Sebastian

AU - Höfling, Sven

AU - Tarucha, Seigo

AU - Fraser, Michael D.

PY - 2024

Y1 - 2024

N2 - Periodic temporal modulation of Hamiltonians can induce geometrical and topological phenomena in the dynamics of quantum states. Using the interference between two lasers, we demonstrate an off-resonant optical lattice for a polariton condensate with controllable potential depths and nearest-neighbour coupling strength. Temporal modulation is introduced via a gigahertz frequency detuning between pump lasers, creating a polariton ‘conveyor belt’. The breaking of time-reversal symmetry causes band structures to become non-reciprocal and acquire a universal tilt given by Planck’s constant and the frequency of modulation (hΔf). The non-reciprocal tilting is connected to the non-trivial topology of the Floquet–Bloch bands, which have a finite Chern number. Detailed characterization of the lattice potential depth and its dynamics highlights the role of high-energy carriers in the formation of optical potential landscapes for polaritons, demonstrating the possibility of modulation faster than the polariton lifetime and opening a pathway towards Floquet engineering in polariton condensates.

AB - Periodic temporal modulation of Hamiltonians can induce geometrical and topological phenomena in the dynamics of quantum states. Using the interference between two lasers, we demonstrate an off-resonant optical lattice for a polariton condensate with controllable potential depths and nearest-neighbour coupling strength. Temporal modulation is introduced via a gigahertz frequency detuning between pump lasers, creating a polariton ‘conveyor belt’. The breaking of time-reversal symmetry causes band structures to become non-reciprocal and acquire a universal tilt given by Planck’s constant and the frequency of modulation (hΔf). The non-reciprocal tilting is connected to the non-trivial topology of the Floquet–Bloch bands, which have a finite Chern number. Detailed characterization of the lattice potential depth and its dynamics highlights the role of high-energy carriers in the formation of optical potential landscapes for polaritons, demonstrating the possibility of modulation faster than the polariton lifetime and opening a pathway towards Floquet engineering in polariton condensates.

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DO - 10.1038/s41566-024-01424-z

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VL - 18

SP - 548

EP - 553

JO - Nature Photonics

JF - Nature Photonics

ER -

Non-reciprocal band structures in an exciton–polariton Floquet optical lattice

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