Parametric Scattering of Cavity Polaritons

Kuwata‐Gonokami, Makoto; Inouye, S.; Suzuura, Hidekatsu; Shirane, Masayuki; Shimano, Ryo; Someya, Takao; Sakaki, H.

doi:10.1103/physrevlett.79.1341

Cited by 132 publications

(113 citation statements)

References 13 publications

Supporting

Mentioning

102

Contrasting

Order By: Relevance

“…20 The latter have indeed been shown to be instrumental in analyzing four-wave mixing experiments performed on GaAs MCs. [21][22][23] The SCR between the biexciton transition and the cavity photon might even be observed in MCs submitted to intense circularly polarized excitation. 24 Compared to III-As or II-VI MQW MCs, disorder and biexcitons should play an even more important role in nitride-based systems.…”

Section: Introductionmentioning

confidence: 99%

Impact of biexcitons on the relaxation mechanisms of polaritons in III-nitride based multiple quantum well microcavities

et al. 2012

View full text Add to dashboard Cite

We report on the direct observation of biexcitons in a III-nitride based multiple quantum well microcavity operating in the strong light-matter coupling regime by means of nonresonant continuous wave and time-resolved photoluminescence at low temperature. First, the biexciton dynamics is investigated for the bare active medium (multiple quantum wells alone) evidencing localization on potential fluctuations due to alloy disorder and thermalization between both localized and free excitonic and biexcitonic populations. Then, the role of biexcitons is considered for the full microcavity: in particular, we observe that for specific detunings the bottom of the lower polariton branch is directly fed by the radiative dissociation of either cavity biexcitons or excitons mediated by one LO-phonon. Accordingly, minimum polariton lasing thresholds are observed, when the bottom of the lower polariton branch corresponds in energy to the exciton or cavity biexciton first LO-phonon replica. This singular observation highlights the role of excitonic molecules in the polariton condensate formation process as being a more efficient relaxation channel when compared to the usually assumed acoustical phonon emission one.

show abstract

Section: Introductionmentioning

confidence: 99%

Impact of biexcitons on the relaxation mechanisms of polaritons in III-nitride based multiple quantum well microcavities

et al. 2012

View full text Add to dashboard Cite

show abstract

“…Similarly when the upper line is pumped, it transiently redshifts by 0.3 meV, leaving the lower line almost unmoved. A complete description of this effect requires account of the bipolariton interactions [20]; however, it strongly resembles an ac Stark effect [12]. In a simplified explanation the intracavity field at v 1 both repels and broadens the higher energy bare exciton line, leading to an increase in v ex but a decrease in v R .…”

mentioning

confidence: 99%

Suppressed Polariton Scattering in Semiconductor Microcavities

Baumberg

Armitage

Skolnick

et al. 1999

Quantum Optoelectronics

View full text Add to dashboard Cite

Ultrafast time-resolved measurements on a semiconductor microcavity distinguish polariton dynamics dependent on the detuning between the constituent photon and exciton modes. Spectral synthesis allows the injection of specific polariton pulses into the sample. Scattering which results in absorption is found to be suppressed in the lower polariton branch by the combined action of normal mode splitting and motional narrowing. The experimental difference between angle and position tuning demonstrates the role of the polariton dispersion in polariton-polariton interactions. [S0031-9007(98) PACS numbers: 71.36. + c, 42.50. -p, 42.65. -k, 78.47. + p Manipulating the interaction between light and semiconductors by engineering the electron and photon states has enabled a variety of striking coherent phenomena to be observed in recent years. By embedding a semiconductor quantum well (QW) inside a wavelength scale optical cavity, strong and tunable coupling between the band-gap excitons and photons produces new polariton modes which dominate the optical spectra [1,2]. Many experiments have probed these microcavity properties using reflection, transmission, and photoluminescence measurements in both cw [3][4][5] and time-resolved [6][7][8] domains. In the former, the two polariton peaks are spectrally resolved, whereas, in the latter, short pulses impulsively drive both polariton branches producing characteristic Rabi oscillations. These investigations mainly track the escape of polaritons from the microcavity via their leakage through the mirrors.In this paper we resolve instead the scattering of polaritons into states in which they are irreversibly absorbed and cannot promptly reradiate. Using spectrally tailored pump pulses in time-resolved nonlinear measurements, distinct differences in absorption are uncovered for the two branches of the polariton dispersion. Although the sample reflects equally strongly on either spectral line when the photon and exciton modes are in resonance, polariton scattering in the lower branch is clearly suppressed. Such behavior was predicted for optic phonon scattering of bulk polaritons [9] but inconclusively verified-in contrast, microcavity samples provide direct access to the polariton modes. These data confirm a recent prediction that the lower branch polariton is more effectively decoupled from localized exciton states [10]. Two methods for tuning the polariton resonance by varying the angle of incidence or the cavity frequency are seen to be inequivalent due to the influence of the polariton dispersion.The semiconductor quantum microcavity (QMC) sample is formed from two distributed Bragg reflectors (DBRs) alternating ten l͞4-thick layers of GaAs and AlAs and contains three 100 Å In 0.06 Ga 0.94 As QWs, 100 Å apart. The optical cavity length is ϳ l ex . Measurements on a piece of the wafer near resonance allow both angle and position tuning of the relative energy (D) between cavity and exciton resonances. The simplest model of this system predicts a characteristic anticrossing th...

show abstract

“…For small inplane wave vectors of the excitons and the photons, the nonlinear interaction constants 2A = 6Ry ex a 2 ex /S and B = g/ (n sat S), where Ry ex is the binding energy of the excitons, S the quantization area and n sat = 7/ 16πa 2 ex is the exciton saturation density [13,21]. The ratio of the exciton-exciton interaction constant A and the phasespace filling factor B may be determined by a degenerate four-wave mixing experiment [22,23]. In this paper, we assume that these two parameters are real and positive.…”

Section: Theoretical Modelmentioning

confidence: 99%

Collapses and revivals of exciton emission in a semiconductor microcavity: Detuning and phase-space filling effects

Jin

Liu

2004

Phys. Rev. A

View full text Add to dashboard Cite

We investigate exciton emission of quantum well embedded in a semiconductor microcavity. The analytical expressions of the light intensity for the cases of excitonic number state and coherent state are presented by using secular approximation. Our results show that the effective exciton-exciton interaction leads to the appearance of collapse and revival of the light intensity. The revival time is twice compared the coherent state case with that of the number state. The dissipation of the exciton-polariton lowers the revival amplitude but does not alter the revival time. The influences of the detuning and the phase-space filling are studied. We find that the effect of the higher-order exciton-photon interaction may be removed by adjusting the detuning.

show abstract

Parametric Scattering of Cavity Polaritons

Cited by 132 publications

References 13 publications

Impact of biexcitons on the relaxation mechanisms of polaritons in III-nitride based multiple quantum well microcavities

Impact of biexcitons on the relaxation mechanisms of polaritons in III-nitride based multiple quantum well microcavities

Suppressed Polariton Scattering in Semiconductor Microcavities

Collapses and revivals of exciton emission in a semiconductor microcavity: Detuning and phase-space filling effects

Contact Info

Product

Resources

About