-
DTU with expertise in design, simulation, nanofabrication, characterization, and application of photonic integrated circuits (PIC). The activities within the project will benefit from synergies with
-
photonic chips yourself using DTU’s own state-of-the-art nanofabrication facility DTU-NanoLab . You will have the opportunity to co-supervise BSc, MSc, and PhDs and we expect you to actively engage in
-
You will participate in a project team with several Postdocs and PhD students, which will design and develop TMD-based and QD-based single-photon sources and detectors meeting all the requirements
-
of light from photonic integrated sources and investigate it in point-to-point and multi-user network configurations. The position will be hosted by the Section of Quantum Physics and Information
-
Postdoc in Continuous-Variable Measurement-Device-Independent Quantum Key Distribution – DTU Physics
this position you will advance continuous-variable measurement-device-independent QKD using photonic integrated chips developed by a collaborator. You will advance performance and security, e.g. by working with
-
for long-distance continuous variable quantum key distribution using a hybrid detection scheme comprising of both photon counting and homodyne detection. This is an incredible opportunity to be part of a
-
photonic crystal fibers covering 400-2400 nm and will use so-called all-normal dispersion (ANDi) fibers pumped with femtosecond lasers to achieve record low noise for spectroscopy and Optical Coherence
-
formal qualification, you must hold a PhD degree (or equivalent). We offer DTU is a leading technical university globally recognized for the excellence of its research, education, innovation, and
-
on solid-core silica photonic crystal fibers covering 400-2400 nm and will use so-called all-normal dispersion (ANDi) fibers pumped with femtosecond lasers to achieve record low noise for spectroscopy and
-
single photon counting direct X-ray installed at the 3D Imaging center at DTU Physics. You will design and take part in the implementation of correlative approaches for plant imaging including X-ray