Vortex stability and permanent flow in nonequilibrium polariton condensates

G. Tosi; D. Sanvitto; M. Baudisch; E. Karimi; B. Piccirillo; L. Marrucci; A. Lematre; J. Bloch; L. Via

doi:10.1063/1.3576151

Vortex stability and permanent flow in nonequilibrium polariton condensates

G. Tosi
, D. Sanvitto
, M. Baudisch
, E. Karimi
, B. Piccirillo
, L. Marrucci
, A. Lematre
, J. Bloch
, L. Via

Universidad Autónoma de Madrid
National Nanotechnology Laboratory, Lecce
University of Naples Federico II
Centre de Nanosciences et de Nanotechnologies

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

Abstract

We study the effects of imprinting a single-quantized vortex on the steady state of a microcavity exciton-polariton condensate generated via parametric scattering. Interestingly we observe two distinct regimes: In the first case, at low polariton densities, the effect of the pulsed probe, containing the vortex state, is to generate a gain response in the condensate lasting for tens of picoseconds during which no dissipation of the circulating currents is detected. In the second regime, at higher densities, the gain lasts much less and the circulation is imprinted directly into the steady state, which acquires permanent rotation for as long as the vortex remains within the condensate. We use two different ways of measuring the circulation of the condensate and demonstrate that in both cases, polariton condensation in the parametric scattering regime can sustain permanent supercurrents.

Original language	English
Article number	102406
Journal	Journal of Applied Physics
Volume	109
Issue number	10
DOIs	https://doi.org/10.1063/1.3576151
Publication status	Published - 15 May 2011
Externally published	Yes

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abstract = "We study the effects of imprinting a single-quantized vortex on the steady state of a microcavity exciton-polariton condensate generated via parametric scattering. Interestingly we observe two distinct regimes: In the first case, at low polariton densities, the effect of the pulsed probe, containing the vortex state, is to generate a gain response in the condensate lasting for tens of picoseconds during which no dissipation of the circulating currents is detected. In the second regime, at higher densities, the gain lasts much less and the circulation is imprinted directly into the steady state, which acquires permanent rotation for as long as the vortex remains within the condensate. We use two different ways of measuring the circulation of the condensate and demonstrate that in both cases, polariton condensation in the parametric scattering regime can sustain permanent supercurrents.",

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T1 - Vortex stability and permanent flow in nonequilibrium polariton condensates

AU - Tosi, G.

AU - Sanvitto, D.

AU - Baudisch, M.

AU - Karimi, E.

AU - Piccirillo, B.

AU - Marrucci, L.

AU - Lematre, A.

AU - Bloch, J.

AU - Via, L.

PY - 2011/5/15

Y1 - 2011/5/15

N2 - We study the effects of imprinting a single-quantized vortex on the steady state of a microcavity exciton-polariton condensate generated via parametric scattering. Interestingly we observe two distinct regimes: In the first case, at low polariton densities, the effect of the pulsed probe, containing the vortex state, is to generate a gain response in the condensate lasting for tens of picoseconds during which no dissipation of the circulating currents is detected. In the second regime, at higher densities, the gain lasts much less and the circulation is imprinted directly into the steady state, which acquires permanent rotation for as long as the vortex remains within the condensate. We use two different ways of measuring the circulation of the condensate and demonstrate that in both cases, polariton condensation in the parametric scattering regime can sustain permanent supercurrents.

AB - We study the effects of imprinting a single-quantized vortex on the steady state of a microcavity exciton-polariton condensate generated via parametric scattering. Interestingly we observe two distinct regimes: In the first case, at low polariton densities, the effect of the pulsed probe, containing the vortex state, is to generate a gain response in the condensate lasting for tens of picoseconds during which no dissipation of the circulating currents is detected. In the second regime, at higher densities, the gain lasts much less and the circulation is imprinted directly into the steady state, which acquires permanent rotation for as long as the vortex remains within the condensate. We use two different ways of measuring the circulation of the condensate and demonstrate that in both cases, polariton condensation in the parametric scattering regime can sustain permanent supercurrents.

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DO - 10.1063/1.3576151

M3 - Article

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SN - 0021-8979

VL - 109

JO - Journal of Applied Physics

JF - Journal of Applied Physics

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ER -

Vortex stability and permanent flow in nonequilibrium polariton condensates

Abstract

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