Electrically Driven Microcavity Exciton-Polariton Optomechanics at 20 GHz

Microcavity exciton polaritons enable the resonant coupling of excitons and photons to vibrations in the super-high-frequency (SHF, 3–30 GHz) domain. We introduce here a novel platform for coherent SHF optomechanics based on the coupling of polaritons and electrically driven SHF longitudinal acousti...

Full description

Bibliographic Details
Main Authors: Alexander S. Kuznetsov, Diego H. O. Machado, Klaus Biermann, Paulo V. Santos
Format: Article
Language:English
Published: American Physical Society 2021-04-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.11.021020
id doaj-479af41ae15a4e5183b9157194a010d7
record_format Article
spelling doaj-479af41ae15a4e5183b9157194a010d72021-04-23T14:28:33ZengAmerican Physical SocietyPhysical Review X2160-33082021-04-0111202102010.1103/PhysRevX.11.021020Electrically Driven Microcavity Exciton-Polariton Optomechanics at 20 GHzAlexander S. KuznetsovDiego H. O. MachadoKlaus BiermannPaulo V. SantosMicrocavity exciton polaritons enable the resonant coupling of excitons and photons to vibrations in the super-high-frequency (SHF, 3–30 GHz) domain. We introduce here a novel platform for coherent SHF optomechanics based on the coupling of polaritons and electrically driven SHF longitudinal acoustic phonons confined in a planar Bragg microcavity. The highly monochromatic phonons with tunable amplitudes are excited over a wide frequency range by piezoelectric transducers, which also act as efficient phonon detectors with a very large dynamical range. The microcavity platform exploits the long coherence time of polaritons as well as their efficient coupling to phonons. Furthermore, an intrinsic property of the platform is the backfeeding of phonons to the interaction region via reflections at the sample boundaries, which leads to quality factor × frequency products (Q×f) exceeding 10^{14}  Hz as well as huge modulation amplitudes of the optical transition energies exceeding 8 meV. We show that the modulation is dominated by the phonon-induced energy shifts of the excitonic polariton component. Thus, the large modulation leads to a dynamical switching of light-matter nature of the particles from a mixed (i.e., polaritonic) one to photonlike and excitonlike states at frequencies up to 20 GHz. On the one hand, this work opens the way for electrically driven polariton optomechanics in the nonadiabatic, sideband-resolved regime of coherent control. Here, the bidirectionality of the transducers can be exploited for light-to-sound-to-rf conversion. On the other hand, the large phonon frequencies and Q×f products enable phonon control with optical readout down to the single-particle regime at relatively high temperatures (of 1 K).http://doi.org/10.1103/PhysRevX.11.021020
collection DOAJ
language English
format Article
sources DOAJ
author Alexander S. Kuznetsov
Diego H. O. Machado
Klaus Biermann
Paulo V. Santos
spellingShingle Alexander S. Kuznetsov
Diego H. O. Machado
Klaus Biermann
Paulo V. Santos
Electrically Driven Microcavity Exciton-Polariton Optomechanics at 20 GHz
Physical Review X
author_facet Alexander S. Kuznetsov
Diego H. O. Machado
Klaus Biermann
Paulo V. Santos
author_sort Alexander S. Kuznetsov
title Electrically Driven Microcavity Exciton-Polariton Optomechanics at 20 GHz
title_short Electrically Driven Microcavity Exciton-Polariton Optomechanics at 20 GHz
title_full Electrically Driven Microcavity Exciton-Polariton Optomechanics at 20 GHz
title_fullStr Electrically Driven Microcavity Exciton-Polariton Optomechanics at 20 GHz
title_full_unstemmed Electrically Driven Microcavity Exciton-Polariton Optomechanics at 20 GHz
title_sort electrically driven microcavity exciton-polariton optomechanics at 20 ghz
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2021-04-01
description Microcavity exciton polaritons enable the resonant coupling of excitons and photons to vibrations in the super-high-frequency (SHF, 3–30 GHz) domain. We introduce here a novel platform for coherent SHF optomechanics based on the coupling of polaritons and electrically driven SHF longitudinal acoustic phonons confined in a planar Bragg microcavity. The highly monochromatic phonons with tunable amplitudes are excited over a wide frequency range by piezoelectric transducers, which also act as efficient phonon detectors with a very large dynamical range. The microcavity platform exploits the long coherence time of polaritons as well as their efficient coupling to phonons. Furthermore, an intrinsic property of the platform is the backfeeding of phonons to the interaction region via reflections at the sample boundaries, which leads to quality factor × frequency products (Q×f) exceeding 10^{14}  Hz as well as huge modulation amplitudes of the optical transition energies exceeding 8 meV. We show that the modulation is dominated by the phonon-induced energy shifts of the excitonic polariton component. Thus, the large modulation leads to a dynamical switching of light-matter nature of the particles from a mixed (i.e., polaritonic) one to photonlike and excitonlike states at frequencies up to 20 GHz. On the one hand, this work opens the way for electrically driven polariton optomechanics in the nonadiabatic, sideband-resolved regime of coherent control. Here, the bidirectionality of the transducers can be exploited for light-to-sound-to-rf conversion. On the other hand, the large phonon frequencies and Q×f products enable phonon control with optical readout down to the single-particle regime at relatively high temperatures (of 1 K).
url http://doi.org/10.1103/PhysRevX.11.021020
work_keys_str_mv AT alexanderskuznetsov electricallydrivenmicrocavityexcitonpolaritonoptomechanicsat20ghz
AT diegohomachado electricallydrivenmicrocavityexcitonpolaritonoptomechanicsat20ghz
AT klausbiermann electricallydrivenmicrocavityexcitonpolaritonoptomechanicsat20ghz
AT paulovsantos electricallydrivenmicrocavityexcitonpolaritonoptomechanicsat20ghz
_version_ 1721512645077499904