-
to develop novel scalable technologies for quantum optical communications. The project is on developing quantum materials and photonic structures to operate in the telecom wavelength as quantum light sources
-
strontium atoms in an optical lattice, and aims at investigating large spin Fermi-Hubbard models with single-atom and single-site resolution by imaging them in a quantum gas microscope. The second one focuses
-
detection, devices with advanced functionalities etc.) Many advanced tools will be available such as (dilution) cryostats with optical access, cryogenic scanning near-field microscope, optical quantum twist
-
lasers based on colloidal quantum dot technology. The aim is to develop the first chip-integrated infrared quantum dot laser emitting in the telecom wavelength regime as well as in longer wavelengths
-
. The successful candidate will be joining the Quantum Nano-Optoelectronics group led by Prof. Dr. Frank Koppens. We aim to manipulate materials in a completely different way, by making them strongly interact with
-
. The successful candidate will be joining the Quantum Optics Theory group led by Prof. Dr. Maciej Lewenstein and will work on the development of quantum information protocols for current quantum information
-
. The successful candidate will be joining the Atomic Quantum Optics group led by Prof. Dr. Morgan Mitchell. The group has several active research topics focused on hot-vapor quantum sensors, including
-
. The successful candidate will be joining the Quantum Optics Theory group led by Prof. Dr. Maciej Lewenstein and will work on the development of quantum information protocols for current quantum information
-
. The successful candidate will be joining the Atomic Quantum Optics group led by Prof. Dr. Morgan Mitchell. Searches for new particles and forces using table-top experiments is an expanding frontier of fundamental