Polariton-enhanced exciton transport

Myers, D. M.; Mukherjee, Smita; Beaumariage, Jonathan; Snoke, D. W.; Steger, Mark; Pfeiffer, L. N.; West, K. W.

doi:10.1103/physrevb.98.235302

Cited by 37 publications

(36 citation statements)

References 42 publications

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“…Although the lifetime of the polaritons is around 200 ps, the time scale for this equilibration is much longer, because there is an interplay between the polariton population and the exciton reservoir with much longer lifetime. A previous study [15] has shown that excitons created by the pump laser diffuse about 30 µm away from the creation spot, but here we see evidence of reservoir excitons all the way around the ring, 150 µm from the creation spot. This indicates that polaritons may convert back into excitons via polariton-polariton collisions.…”

Section: Methodscontrasting

confidence: 46%

Observation of nonequilibrium motion and equilibration in polariton rings

et al. 2019

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We present a study of the macroscopic dynamics of a polariton condensate formed by non-resonant optical excitation in a quasi-one-dimensional ring shaped microcavity. The presence of a gradient in the cavity photon energy creates a macroscopic trap for the polaritons in which a single mode condensate is formed. With time-and energy-resolved imaging we show the role of interactions in the motion of the condensate as it undergoes equilibration in the ring. These experiments also give a direct measurement of the polariton-polariton interaction strength above the condensation threshold. Our observations are compared to the open-dissipative one-dimensional Gross-Pitaevskii equation which shows excellent qualitative agreement.

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confidence: 46%

Observation of nonequilibrium motion and equilibration in polariton rings

et al. 2019

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“…One possibility is that, while the diffusion of the heavy excitons in these samples is considered to be small (of the order of ∼ 1 µm), the reservoir composed of mobile, high-momentum bottleneck polaritons could result in a significant diffusion into the centre of the trap. This possibility is supported by the recent study [28], which found the diffusion lengths of the highly excitonic polaritons at high k to be greater than 20 µm. It is also supported by the observation here and in Ref.…”

Section: Discussionmentioning

confidence: 55%

Effect of optically induced potential on the energy of trapped exciton polaritons below the condensation threshold

et al. 2019

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Exciton-polaritons (polaritons herein) offer a unique nonlinear platform for studies of collective macroscopic quantum phenomena in a solid state system. Shaping of polariton flow and polariton confinement via potential landscapes created by nonresonant optical pumping has gained considerable attention due to the degree of flexibility and control offered by optically-induced potentials. Recently, large density-dependent energy shifts (blueshifts) exhibited by optically trapped polaritons at low densities, below the bosonic condensation threshold, were interpreted as an evidence of strong polariton-polariton interactions [Nat. Phys. 13, 870 (2017)]. In this work, we further investigate the origins of these blueshifts in optically-induced circular traps and present evidence of significant blueshift of the polariton energy due to reshaping of the optically-induced potential with laser pump power. Our work demonstrates strong influence of the effective potential formed by an optically-injected excitonic reservoir on the energy blueshifts observed below and up to the polariton condensation threshold and suggests that the observed blueshifts arise due to interaction of polaritons with the excitonic reservoir, rather than due to polariton-polariton interaction. arXiv:1808.00749v3 [cond-mat.quant-gas]

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“…In this work, the ultrastrong coupling of a Bloch surface wave photon and molecular excitons in a disordered organic thin-film at room temperature is demonstrated, where the major fraction of the polaritons are propagating states. The delocalized exciton-polariton has a group velocity as high as 3×10 7 m/s and a lifetime of 500 fs, leading to propagation distances of over one hundred microns from the excitation source. The polariton intensity shows a halo-like pattern that is due to self-interference of the polariton mode, from which we derive a coherence length of 20 μm and correlate it with phase-breaking of polariton scattering.…”

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confidence: 99%

“…Thus, a promising means to improve energy transport is to strongly couple excitons with photons in an optical cavity, forming new quantum mechanical quasi-particles called excitonpolaritons. [6][7][8][9][10] Polaritons partially inherit the light effective mass and delocalization properties rendered by their photonic component, and thus are potentially immune from interactions with local defects and disorder common to molecular solids. [11][12][13] Coherent coupling with an extended and propagating photon mode can lead to rapid and long-range transport that differs from the slow and short-range diffusion of more massive excitons.…”

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confidence: 99%

“…[17] This distance, however, is almost one order of magnitude smaller than that typically observed for inorganic crystalline cavity polaritons at cryogenic temperatures. [7] In this work, we investigate room temperature polariton propagation in an all-dielectric photonic structure comprising a disordered molecular thin-film of tetraphenyldibenzoperiflanthene (DBP), a model organic electronic molecule, deposited onto the surface of a distributed Bragg reflector (DBR). Similar to the surface confined and propagating modes of one-dimensional or twodimensional photonic crystals, [18,19] the truncated periodic multilayers of DBR support a Bloch surface mode, of which its strong electric-field enhancement and low optical loss is ideal for strong coupling with excitons and long-range transport applications.…”

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Ultralong‐Range Energy Transport in a Disordered Organic Semiconductor at Room Temperature Via Coherent Exciton‐Polariton Propagation

et al. 2020

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Amorphous molecular solids are inherently disordered, exhibiting strong exciton localization. Optical microcavities containing such disordered excitonic materials have been theoretically shown to support both propagating and localized exciton‐polariton modes. Here, the ultrastrong coupling of a Bloch surface wave photon and molecular excitons in a disordered organic thin film at room temperature is demonstrated, where the major fraction of the polaritons are propagating states. The delocalized exciton‐polariton has a group velocity as high as 3 × 107 m s–1 and a lifetime of 500 fs, leading to propagation distances of over 100 µm from the excitation source. The polariton intensity shows a halo‐like pattern that is due to self‐interference of the polariton mode, from which a coherence length of 20 µm is derived and is correlated with phase breaking by polariton scattering. The demonstration of ultralong‐range exciton‐polariton transport at room temperature promises new photonic and optoelectronic applications such as efficient energy transfer in disordered condensed matter systems.

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Polariton-enhanced exciton transport

Cited by 37 publications

References 42 publications

Observation of nonequilibrium motion and equilibration in polariton rings

Observation of nonequilibrium motion and equilibration in polariton rings

Effect of optically induced potential on the energy of trapped exciton polaritons below the condensation threshold

Ultralong‐Range Energy Transport in a Disordered Organic Semiconductor at Room Temperature Via Coherent Exciton‐Polariton Propagation

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