In a microcavity, light-matter coupling is quantified by the vacuum Rabi
frequency $\Omega_R$. When $\Omega_R$ is larger than radiative and
non-radiative loss rates, the system eigenstates (polaritons) are linear
superposition of photonic and electronic excitations, a condition actively
investigated in diverse physical implementations. Recently, a quantum
electrodynamic regime (ultra-strong coupling) was predicted when $\Omega_R$
becomes comparable to the transition frequency. Here we report unambiguous
signatures of this regime in a quantum-well intersubband microcavity. Measuring
the cavity-polariton dispersion in a room-temperature linear optical
experiment, we directly observe the anti-resonant light-matter coupling and the
photon-energy renormalization of the vacuum field

Anappara, Aji A.

Beltram, Fabio

Biasiol, Giorgio

Ciuti, Cristiano

De Liberato, Simone

Sorba, Lucia

Tredicucci, Alessandro

English

arXiv

In a microcavity, light-matter coupling is quantified by the vacuum-Rabi frequency Omega(R). When Omega(R) is larger than radiative and nonradiative loss rates, the system eigenstates (polaritons) are linear superposition of photonic and electronic excitations, a condition actively investigated in diverse physical implementations. Recently, a quantum electrodynamic regime (ultrastrong coupling) was predicted when Omega(R) becomes comparable to the transition frequency. Here we report signatures of this regime in a quantum-well intersubband microcavity. Measuring the cavity-polariton dispersion in a room-temperature linear optical experiment, we directly observe the antiresonant light-matter coupling and the photon-energy renormalization of the vacuum field

A. A. ANAPPARA

S. DE LIBERATO

A. TREDICUCCI

C. CIUTI

G. BIASIOL

L. SORBA

BELTRAM, Fabio

Archivio istituzionale della Ricerca - Scuola Normale Superiore

Signatures of the ultrastrong light-matter coupling regime

International audienceIn a microcavity, light-matter coupling is quantified by the vacuum Rabi frequency $\Omega_R$. When $\Omega_R$ is larger than radiative and non-radiative loss rates, the system eigenstates (polaritons) are linear superposition of photonic and electronic excitations, a condition actively investigated in diverse physical implementations. Recently, a quantum electrodynamic regime (ultra-strong coupling) was predicted when $\Omega_R$ becomes comparable to the transition frequency. Here we report unambiguous signatures of this regime in a quantum-well intersubband microcavity. Measuring the cavity-polariton dispersion in a room-temperature linear optical experiment, we directly observe the anti-resonant light-matter coupling and the photon-energy renormalization of the vacuum field

de Liberato, Simone

Hal-Diderot

Light-matter excitations in the ultra-strong coupling regime

Aji A. Anappara

Simone De Liberato

Alessandro Tredicucci

Cristiano Ciuti

Giorgio Biasiol

Lucia Sorba

Fabio Beltram

Crossref

In a microcavity, light-matter coupling is quantified by the vacuum-Rabi frequency ?R. When ?R is larger than radiative and nonradiative loss rates, the system eigenstates (polaritons) are linear superposition of photonic and electronic excitations, a condition actively investigated in diverse physical implementations. Recently, a quantum electrodynamic regime (ultrastrong coupling) was predicted when ?R becomes comparable to the transition frequency. Here we report signatures of this regime in a quantum-well intersubband microcavity. Measuring the cavity-polariton dispersion in a room-temperature linear optical experiment, we directly observe the antiresonant light-matter coupling and the photon-energy renormalization of the vacuum field

Southampton (e-Prints Soton)

In a microcavity, light-matter coupling is quantified by the vacuum-Rabi frequency Omega_R. When Omega_R is larger than radiative and nonradiative loss rates, the system eigenstates (polaritons) are linear superposition of photonic and electronic excitations, a condition actively investigated in diverse physical implementations. Recently, a quantum electrodynamic regime (ultrastrong coupling) was predicted when Omega_R becomes comparable to the transition frequency. Here we report signatures of this regime in a quantum-well intersubband microcavity. Measuring the cavity-polariton dispersion in a room-temperature linear optical experiment, we directly observe the antiresonant light-matter coupling and the photon-energy renormalization of the vacuum field

Light-matter excitations in the ultra-strong coupling regime

Abstract

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Archivio istituzionale della Ricerca - Scuola Normale Superiore

Hal-Diderot

Crossref

Southampton (e-Prints Soton)

Archivio della Ricerca - Università di Pisa