Controlling the Spontaneous Emission Rate of Single Quantum Dots in a Two-Dimensional Photonic Crystal

Englund, Dirk; Fattal, David; Waks, Edo; Solomon, Glenn S.; Zhang, Bingyang; Nakaoka, Toshihiro; Arakawa, Yasuhiko; Yamamoto, Yoshihisa; Vučković, Jelena

doi:10.1103/physrevlett.95.013904

Cited by 904 publications

(659 citation statements)

References 14 publications

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“…These nanoscale cavities are enabling the study of fundamentally new regimes of light-matter interaction, such as single-exciton QED [47]. Therefore, the most common PC structure to date for trying to demonstrate a single photon source is the PC cavity [48][49][50].…”

Section: Single Photon Emission Within a Pc Cavitymentioning

confidence: 99%

On‐chip single photon sources using planar photonic crystals and single quantum dots

Yao

Rao

Hughes³

2010

Laser & Photonics Reviews

157

184

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We review the basic light-matter interactions and optical properties of chip-based single photon sources, that are enabled by integrating single quantum dots with planar photonic crystals. A theoretical framework is presented that allows one to connect to a wide range of quantum light propagation effects in a physically intuitive and straightforward way. We focus on the important mechanisms of enhanced spontaneous emission, and efficient photon extraction, using all-integrated photonic crystal components including waveguides, cavities, quantum dots and output couplers. The limitations, challenges, and exciting prospects of developing on-chip quantum light sources using integrated photonic crystal structures are discussed.A sequence of optical pulses (top right) interacting with a single quantum dot embedded in a photonic crystal system, resulting in the emission of a train of single photons on-chip.

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Section: Single Photon Emission Within a Pc Cavitymentioning

confidence: 99%

On‐chip single photon sources using planar photonic crystals and single quantum dots

Yao

Rao

Hughes³

2010

Laser & Photonics Reviews

157

184

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“…[22][23][24][25] Emitters coupled to cavities can also serve as highly nonlinear devices operating at low photon numbers, 26 as well as efficient interfaces between photons and solid-state quantum memory. 27,28 The majority of the work to-date focused on a single emitter in a cavity, which can exhibit nearly perfect single photon purity and indistinguishability using resonant pumping techniques.…”

mentioning

confidence: 99%

Two-Photon Interference from the Far-Field Emission of Chip-Integrated Cavity-Coupled Emitters

et al. 2016

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ABSTRACT. Interactions between solid-state quantum emitters and cavities are important for a broad range of applications in quantum communication, linear optical quantum computing, nonlinear photonics, and photonic quantum simulation. These applications often require combining many devices on a single chip with identical emission wavelengths in order to generate two-photon interference, the primary mechanism for achieving effective photon-photon interactions. Such integration remains extremely challenging due to inhomogeneous broadening and fabrication errors that randomize the resonant frequencies of both the emitters and cavities. In this letter we demonstrate two-photon interference from independent cavity-coupled emitters on the same chip, providing a potential solution to this long-standing problem. We overcome spectral mismatch between different cavities due to fabrication errors by depositing and locally evaporating a thin layer of condensed nitrogen. We integrate optical heaters to tune individual dots within each cavity to the same resonance with better than 3 µeV of precision. Combining these tuning methods, we demonstrate two-photon interference between two devices spaced by less than 15 µm on the same chip with a post-selected visibility of 33%. These results pave the way to integrate multiple quantum light sources on the same chip to develop quantum photonic devices.

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“…Efficient devices necessitate the coupling of a transition dipole of the dot to a single mode of a 3D microcavity [19,20]. The efficiency of collection is dictated by the ability to couple, both spectrally and spatially, the quantum dot and the cavity mode, as well as properties related to the cavity mode itself.…”

Section: Microcavitiesmentioning

confidence: 99%

“…Efficient devices require the quantum dot to be placed in a single mode, high finesse, small volume microcavity [16,17]. The cavity serves to modify the photon emission dynamics [18] enhancing device efficiency [17,19,20], as well as directing the emission from the dot for efficient coupling to an external optical system. It is the ease with which quantum dots can be integrated with monolithic semiconductor devices that makes them promising as a scalable technology for single and entangled photon pair generators.…”

Section: Introductionmentioning

confidence: 99%

Directed self‐assembly of single quantum dots for telecommunication wavelength optical devices

Dalacu¹,

Reimer

Frédérick

et al. 2010

Laser & Photonics Reviews

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Strong confinement of charges in few electron systems such as in atoms, molecules and quantum dots leads to a spectrum of discrete energy levels that are often shared by several degenerate quantum states. Since the electronic structure is key to understanding their chemical properties, methods that probe these energy levels in situ are important. We show how electrostatic force detection using atomic force microscopy reveals the electronic structure of individual and coupled self-assembled quantum dots. An electron addition spectrum in the Coulomb blockade regime, resulting from a change in cantilever resonance frequency and dissipation during tunneling events, shows one by one electron charging of a dot. The spectra show clear level degeneracies in isolated quantum dots, supported by the first observation of predicted temperature-dependent shifts of Coulomb blockade peaks. Further, by scanning the surface we observe that several quantum dots may reside on what topologically appears to be just one. These images of grouped weakly and strongly coupled dots allow us to estimate their relative coupling strengths.

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Controlling the Spontaneous Emission Rate of Single Quantum Dots in a Two-Dimensional Photonic Crystal

Cited by 904 publications

References 14 publications

On‐chip single photon sources using planar photonic crystals and single quantum dots

On‐chip single photon sources using planar photonic crystals and single quantum dots

Two-Photon Interference from the Far-Field Emission of Chip-Integrated Cavity-Coupled Emitters

Directed self‐assembly of single quantum dots for telecommunication wavelength optical devices

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