Naoto Kumagai scite author profile

Strong coupling of photons and materials 1 in semiconductor nanocavity systems has been investigated because of its potentials in quantum information processing 2 and related applications, and has been testbeds for cavity quantum electrodynamics (QED) 3,4 . Interesting phenomena such as coherent exchange of a single quantum between a single quantum dot and an optical cavity, called vacuum Rabi oscillation 5-9 , and highly efficient cavity QED lasers 10-18 have been reported thus far.The coexistence of vacuum Rabi oscillation and laser oscillation appears to be contradictory in nature, because the fragile reversible process may not survive in laser oscillation. However, recently, it has been theoretically predicted that the strong-coupling effect could be sustained in laser oscillation in properly designed semiconductor systems 19 . Nevertheless, the experimental realization of this phenomenon has remained difficult since the first demonstration of the strong-coupling 5, 6 , because an extremely high cavity quality factor and strong light-matter coupling are both required for this purpose. Here, we demonstrate the onset of laser oscillation in the strong-coupling regime in a single quantum dot (SQD)-cavity system. A high-quality semiconductor optical nanocavity and strong SQD-field coupling enabled to the onset of lasing while maintaining the fragile coherent exchange of quanta between the SQD and the cavity. In addition to the interesting physical features, this device is seen as a prototype of an ultimate solid state light source with an SQD gain, which operates at ultra-low power, with expected applications in future nanophotonic integrated systems and monolithic quantum information devices.

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Spontaneous Two-Photon Emission from a Single Quantum Dot

Ota

et al. 2011

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Spontaneous two photon emission from a solid-state single quantum emitter is observed. We investigated photoluminescence from the neutral biexciton in a single semiconductor quantum dot coupled with a high Q photonic crystal nanocavity. When the cavity is resonant to the half energy of the biexciton, the strong vacuum field in the cavity inspires the biexciton to simultaneously emit two photons into the mode, resulting in clear emission enhancement of the mode. Meanwhile, suppression was observed of other single photon emission from the biexciton, as the two photon emission process becomes faster than the others at the resonance.

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Circularly Polarized Light Emission from Semiconductor Planar Chiral Nanostructures

et al. 2011

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We demonstrate circularly polarized light emission from InAs quantum dots embedded in the waveguide region of a GaAs-based chiral nanostructure. The observed phenomenon originates due to a strong imbalance between left- and right-circularly polarized components of the vacuum field and results in a degree of polarization as high as 26% at room temperature. A strong circular anisotropy of the vacuum field modes inside the chiral nanostructure is visualized using numerical simulation. The results of the simulation agree well with experimental results.

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Room temperature continuous-wave lasing in photonic crystal nanocavity

Nomura¹,

Iwamoto²,

Watanabe³

et al. 2006

Opt. Express

191

119

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We demonstrate room temperature continuous-wave laser operation at 1.3 mum in a photonic crystal nanocavity with InAs/GaAs self-assembled quantum dots by optical pumping. By analyzing a coupled rate equation and the experimental light-light characteristic plot, we evaluate the spontaneous emission coupling factor of the laser to be ~ 0.22. Three-dimensional carrier confinement and a low transparent carrier density due to volume effect in a quantum dot system play important roles in the cw laser operation at room temperature as well as a high quality factor photonic crystal nanocavity.

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Photonic crystal nanocavity laser with a single quantum dot gain

Nomura¹,

Kumagai²,

Iwamoto³

et al. 2009

Opt. Express

118

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We demonstrate a photonic crystal nanocavity laser essentially driven by a self-assembled InAs/GaAs single quantum dot gain. The investigated nanocavities contain only 0.4 quantum dots on an average; an ultra-low density quantum dot sample (1.5 x 10(8) cm(-2)) is used so that a single quantum dot can be isolated from the surrounding quantum dots. Laser oscillation begins at a pump power of 42 nW under resonant condition, while the far-detuning conditions require ~145 nW for lasing. This spectral detuning dependence of laser threshold indicates substantial contribution of the single quantum dot to the total gain. Moreover, photon correlation measurements show a distinct transition from anti-bunching to Poissonian via bunching with the increase of the excitation power, which is also an evidence of laser oscillation using the single quantum dot gain.

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Naoto Kumagai

Laser oscillation in a strongly coupled single-quantum-dot–nanocavity system

Spontaneous Two-Photon Emission from a Single Quantum Dot

Circularly Polarized Light Emission from Semiconductor Planar Chiral Nanostructures

Room temperature continuous-wave lasing in photonic crystal nanocavity

Photonic crystal nanocavity laser with a single quantum dot gain

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