Charged quantum dot micropillar system for deterministic light-matter interactions

Abstract: Quantum dots (QDs) are semiconductor nanostructures in which a three-dimensional potential trap produces an electronic quantum confinement, thus mimicking the behavior of single atomic dipole-like transitions. However, unlike atoms, QDs can be incorporated into solid-state photonic devices such as cavities or waveguides that enhance the light-matter interaction. A near unit efficiency light-matter interaction is essential for deterministic, scalable quantum-information (QI) devices. In this limit, a single pho… Show more

“…Hence, the wavelength and polarization resonance can be shaped using simple metal deposition techniques. This avoids the need to etch the QDcontaining layers, which is thought to lead to charge noise in the structure [15], [16]. CTPs have already been demonstrated in several QD-based applications such as lasers [17] and single-photon sources [18], [19] but to our knowledge have never been considered in the telecoms wavelength regime.…”

Tamm plasmons for efficient interaction of telecom wavelength photons and quantum dots

“…Hence, the wavelength and polarization resonance can be shaped using simple metal deposition techniques. This avoids the need to etch the QDcontaining layers, which is thought to lead to charge noise in the structure [15], [16]. CTPs have already been demonstrated in several QD-based applications such as lasers [17] and single-photon sources [18], [19] but to our knowledge have never been considered in the telecoms wavelength regime.…”

Tamm plasmons for efficient interaction of telecom wavelength photons and quantum dots

“…Further, we show how Purcell factors up to 4.5 with a total of 16 pairs of substrate and 15 top pairs distributed Bragg reflector can be achieved for wavelength scale hemispheres. With careful spectral and spetial mode engineering and colour centres with low phonon coupling, these structures may hold a key element to potential resonant scattering experiments (Noda et al 2007;Androvitsaneas et al 2016). We concluded with an experimental proposal for the realisation of the here simulated polymer structures.…”

Polymer photonic microstructures for quantum applications and sensing

“…• induced by a single hole spin [64] or electron spin [65]. However, these experiments were performed in weakly coupled cavity-QED systems [66][67][68] (similar to waveguide-QED structures [69,70]) with lower device performance, e.g., suffering from spectral diffusion of QD, low P max , low or no SPT gain, and vulnerable to quantum or classical fluctuations and electric/magnetic fields.…”

Spin-based single-photon transistor, dynamic random access memory, diodes, and routers in semiconductors