www.polaritonics.org - Fainstein 12/09/2024

Exciton-Polariton Continuous Time Crystal with an Optomechanical Clock

Prof. Alex Fainstein , Centro Atómico Bariloche and Instituto Balseiro, Bariloche, Argentina.

12/09/2024, 15:00 CET

Abstract

Time crystals (TCs) broadly refer to the spontaneous breaking of time translation symmetry in quantum systems paralleling the similar concept of spatial symmetry breaking evidenced in crystalline matter. In this context, so-called discrete time crystals (DTCs) have been demonstrated in diverse physical systems including cold atoms, magnons in superfluid <sub>3</sub>He, nuclear spins, photonic devices, and quantum computer qubits. DTC behavior is typically evidenced by the emergence of period doubling upon a time-dependent external drive. Very recently also continuous time crystals (CTCs) have been proposed in open quantum systems perturbed from their equilibrium with a time-independent drive [1]. We reveal, through both ultra-high resolution spectroscopy and time-resolved spatial first-order coherence function g(1)(r,t) experiments, that the exciton-polariton ground state in a trap can develop a non-linear self-sustained dynamics, intimately affected by mechanics in ways that expose characteristics of both CTCs and DTCs [2]. In contrast to other realizations, here the TC phases can be controlled by the power of continuous-wave non-resonant optical drive exciting the condensate, and by the optomechanical interactions with phonons [3]. Those phases are, for increasing power, (i) Larmor -like precession of pseudo-spins - a limit-cycle signature of continuous TC, (ii) locking of the frequency of precession to self-sustained coherent phonons - stabilized TC, (iii) doubling of TC’s period by phonons - a DTC with continuous excitation. Non-Hermiticity, non-linearity, dissipative coupling between the polariton pseudo-spin states, and non-adiabatic coupling to a dynamical reservoir, are shown to be important ingredients for the observation of the spontaneous breaking of time-symmetry in such a many-body quantum system. Prospects for the realization of coupled polariton time-crystals, and their optomechanical control, will be also discussed.

[1] P. Kongkhambut et al, Science 377, 670 (2022).

[2] I. Carraro-Haddad et al, Science 384, 995 (2024).

[3] A. S. Kuznetsov et al, Nature Communications 14, 5470 (2023).

About the speaker

Professor Alex Fainstein is a distinguished member of the Photonics & Optoelectronics Group at Centro Atómico Bariloche. He serves as a Full Professor at the Balseiro Institute and is a Senior Researcher at CONICET (National Scientific and Technical Research Council of Argentina). Professor Fainstein earned his PhD from Balseiro Institute and subsequently held fellowships with the Alexander von Humboldt Foundation and the Max Planck Society of Germany (MPI-FKF Stuttgart). He also served as an Associate Researcher at CNRS (National Center for Scientific Research) in France, working with CNET Laboratories, France Telecom, before returning to Argentina. He is a member of both the National Academy of Exact, Physical, and Natural Sciences and the Academy of Sciences of Argentina, and received awards both in Argentina and internationally. His current research interests lie at the intersection of cavity optomechanics and cavity polaritonics in semiconductor resonators.

Date & Location

The event will be taking place online on the 12th of September 2024 at 15:00 CET. Please join using this link.

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