2018
DOI: 10.1103/physrevlett.121.067401
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Generation of Quantized Polaritons below the Condensation Threshold

Abstract: Exciton polaritons in high quality semiconductor microcavities can travel long macroscopic distances (>100  μm) due to their ultralight effective mass. The polaritons are repelled from optically pumped exciton reservoirs where they are formed; however, their spatial dynamics is not as expected for pointlike particles. Instead we show polaritons emitted into waveguides travel orthogonally to the repulsive potential gradient and can only be explained if they are emitted as macroscopic delocalized quantum particl… Show more

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Cited by 8 publications
(9 citation statements)
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“…Our experiment and modeling suggest that the significant blueshift of the polariton energy at low densities originates from the interactions of the polaritons with the reservoir, rather than solely from polaritonpolariton interactions. At very low densities and pump powers, photon-like polaritons experience a strong quantum confinement effect [24][25][26], which results in quantisation of energy levels which dominates the blueshift as the shape of the trapping barrier changes with the increasing pump power. The quantum confinement effect for exciton-like polaritons in large-area traps is negligible, but the significant shifts of the lowest polariton energy at zero momentum are caused by the rising bottom of the potential trap due to the spreading of the excitonic reservoir.…”
Section: Introductionmentioning
confidence: 99%
“…Our experiment and modeling suggest that the significant blueshift of the polariton energy at low densities originates from the interactions of the polaritons with the reservoir, rather than solely from polaritonpolariton interactions. At very low densities and pump powers, photon-like polaritons experience a strong quantum confinement effect [24][25][26], which results in quantisation of energy levels which dominates the blueshift as the shape of the trapping barrier changes with the increasing pump power. The quantum confinement effect for exciton-like polaritons in large-area traps is negligible, but the significant shifts of the lowest polariton energy at zero momentum are caused by the rising bottom of the potential trap due to the spreading of the excitonic reservoir.…”
Section: Introductionmentioning
confidence: 99%
“…So far, there have been several studies addressing the potential in nonresonant all-optical control to manipulate the flow of condensate polaritons. This includes planar waveguiding effects [32,33], barricading signals (transistor switches) [26,34], amplification [16,35], and tailoring the condensate momentum distribution [36]. However, to our knowledge, there has been no investigation on planar microlensing of exciton-polaritons.…”
Section: Focal Regionmentioning
confidence: 99%
“…As the excitonic reservoir behaves as a barrier for polaritons, our two-beam configuration imposes an additional confinement for polaritons in the longitudinal direction of the microrod. Thus, it is possible that this additional quantum confinement will change the energy of the polariton states . What’s more, as pointed out recently by Pieczarka et al, the change of laser power may lead to changes for nonthermalized polariton distribution and thus cause a blueshift in spectroscopic measurements.…”
mentioning
confidence: 92%