Observation of large spontaneous emission rate enhancement of quantum dots in a broken-symmetry slow-light waveguide

Quantum states of light and matter can be manipulated on the nanoscale to provide a technological resource for aiding the implementation of scalable photonic quantum technologies [1-3]. Experimental progress relies on the quality and efficiency of the coupling between photons and internal states of quantum emitters [4-6]. Here we demonstrate a nanophotonic waveguide platform with embedded quantum dots (QDs) that enables both Purcell-enhanced emission and strong chiral coupling. The design uses slow-light effects in a glide-plane photonic crystal waveguide with QD tuning to match the emission frequency to the slow-light region. Simulations were used to map the chirality and Purcell enhancement depending on the position of a dipole emitter relative to the air holes. The highest Purcell factors and chirality occur in separate regions, but there is still a significant area where high values of both can be obtained. Based on this, we first demonstrate a record large radiative decay rate of 17 ns^-1 (60 ps lifetime) corresponding to a 20 fold Purcell enhancement. This was achieved by electric-field tuning of the QD to the slow-light region and quasi-resonant phonon-sideband excitation. We then demonstrate a 5 fold Purcell enhancement for a dot with high degree of chiral coupling to waveguide modes, substantially surpassing all previous measurements. Together these demonstrate the excellent prospects for using QDs in scalable implementations of on-chip spin-photonics relying on chiral quantum optics.Comment: 15 pages, 4 figures, 1 table. Supporting information is available upon request to the corresponding autho

Observation of large spontaneous emission rate enhancement of quantum dots in a broken-symmetry slow-light waveguide

AbstractQuantum states of light and matter can be manipulated on the nanoscale to provide a technological resource for aiding the implementation of scalable photonic quantum technologies. Experimental progress relies on the quality and efficiency of the coupling between photons and internal spin states of quantum emitters. Here we demonstrate a nanophotonic waveguide platform with embedded quantum dots (QDs) that enables both Purcell-enhanced emission and strong chiral coupling. The design uses slow-light effects in a glide-plane photonic crystal waveguide with QD tuning to match the emission frequency to the slow-light region. Simulations were used to map the chirality and Purcell enhancement depending on the position of a dipole emitter relative to the air holes. The highest Purcell factors and chirality occur in separate regions, but there is still a significant area where high values of both can be obtained. Based on this, we first demonstrate a record large radiative decay rate of 17 ± 2 ns−1 (60 ± 6 ps lifetime) corresponding to a 20 ± 2 fold Purcell enhancement. This was achieved by electric-field tuning of the QD to the slow-light region and quasi-resonant phonon-side band excitation. We then demonstrate a 5 ± 1 fold Purcell enhancement for a dot with high degree of chiral coupling to waveguide modes, substantially surpassing all previous measurements. Together these demonstrate the excellent prospects for using QDs in scalable implementations of on-chip spin-photonics relying on chiral quantum optics.</jats:p

Real-time vapour sensing using an OFET-based electronic nose and genetic programming

Electronic noses (e-noses) are increasingly being used as vapour sensors in a range of application areas. E-noses made up of arrays of organic field-effect transistors (OFETs) are particularly valuable due the range and diversity of the information which they provide concerning analyte binding. This study demonstrates that arrays of OFETs, when combined with a data analysis technique using Genetic Programming (GP), can selectively detect airborne analytes in real time. The use of multiple parameters – on resistance, off current and mobility – collected from multiple transistors coated with different semiconducting polymers gives dramatic improvements in the sensitivity (true positive rate), specificity (true negative rate) and speed of sensing. Computer-controlled data collection allows the identification of analytes in real-time, with a time-lag between exposure and detection of the order of 4 s

De Samarcande à Istanbul : étapes orientales

Grand helléniste, arpenteur de terres et de textes, Pierre Chuvin double son érudition académique de professeur des Universités d'un intérêt vivant pour les mondes de l'Asie centrale et de la Turquie sous leurs aspects les plus divers. Ainsi a-t-il fondé et dirigé l'Institut français d'études sur l'Asie centrale (1993-1998), avant de prendre la tête de l'Institut d'études anatoliennes (2003-2008). Succédant à un premier recueil d'hommages consacré au monde grec du mythos au logos, le présent volume rassemble des contributions consacrées à l'Orient centrasiatique et turc. Leur diversité est à l'image de la curiosité inlassable de celui auquel elles sont dédiées. Des mausolées de Samarcande à la Sublime Porte, de l'Antiquité à l'époque contemporaine, de l'écrit à l'image, de l'Histoire à l'aventure, de la mythologie à la médecine, sans oublier la poésie, ce sont les facettes très multiples d'une culture d'une extrême richesse qui sont illustrées ici. Écrits par des chercheurs de plusieurs pays, les textes réunis et présentés dans cet ouvrage de référence renouvellent notre approche d'un monde fascinant et trop souvent méconnu