Add to ORKGWe demonstrate electrically-driven entangled photon generation using a semiconductor quantum dot embedded in a light emitting diode structure. The entanglement is shown to be of sufficient fidelity for applications such as quantum key distribution. © 2010 Optical Society of America
We present measurements on electrically generated photons from a quantum dot in an LED structure, sh...
Lasers and LEDs have a statistical distribution in the number of photons emitted within a given time...
Typical applications of quantum light require optical sources which generate either individual photo...
We demonstrate electrically-driven entangled photon generation using a semiconductor quantum dot emb...
Electrically-driven entangled photon generation is demonstrated for the first time using a single se...
Electrically-driven entangled-photon generation is demonstrated for the first time using a single In...
Existing sources of entangled photons require a laser excitation, imposing a practical limit on thei...
An optical quantum computer, powerful enough to solve problems so far intractable using conventional...
Entangled photons are essential for scalable optical quantum communication and processing. We demons...
Semiconductor quantum dots (QDs) are a promising source of quantum light, combining sub-Poissonian p...
We discuss recent progress using the radiative emission of single quantum dots as a triggered source...
Sources of entangled pairs of photons can be used for encoding signals in quantum-encrypted communic...
Quantum information technology promises to offer incredible advantages over current digital systems,...
The generation of entangled photon pairs is a fundamental cornerstone of quantum optics, and an esse...
We present measurements on electrically generated photons from a quantum dot in an LED structure, sh...
We present measurements on electrically generated photons from a quantum dot in an LED structure, sh...
Lasers and LEDs have a statistical distribution in the number of photons emitted within a given time...
Typical applications of quantum light require optical sources which generate either individual photo...
We demonstrate electrically-driven entangled photon generation using a semiconductor quantum dot emb...
Electrically-driven entangled photon generation is demonstrated for the first time using a single se...
Electrically-driven entangled-photon generation is demonstrated for the first time using a single In...
Existing sources of entangled photons require a laser excitation, imposing a practical limit on thei...
An optical quantum computer, powerful enough to solve problems so far intractable using conventional...
Entangled photons are essential for scalable optical quantum communication and processing. We demons...
Semiconductor quantum dots (QDs) are a promising source of quantum light, combining sub-Poissonian p...
We discuss recent progress using the radiative emission of single quantum dots as a triggered source...
Sources of entangled pairs of photons can be used for encoding signals in quantum-encrypted communic...
Quantum information technology promises to offer incredible advantages over current digital systems,...
The generation of entangled photon pairs is a fundamental cornerstone of quantum optics, and an esse...
We present measurements on electrically generated photons from a quantum dot in an LED structure, sh...
We present measurements on electrically generated photons from a quantum dot in an LED structure, sh...
Lasers and LEDs have a statistical distribution in the number of photons emitted within a given time...
Typical applications of quantum light require optical sources which generate either individual photo...