Research Areas - (3) NV Center Diamond Nanophotonic Quantum Sensing

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Department(s)/lab(s): Physics – Institute of Physics (IPHYS) | Laboratory of Quantum and Nano-Optics (LQNO, Galland Group) @ EPFL
Summary:

Galland leads LQNO at EPFL investigating light-matter interactions in nano-structures and the quantum regime. Research directions: (1) NV centers in diamond for quantum sensing — spectroscopy of NV spin states in ultra-thin diamond membranes, development of diamond nanophotonic platforms for enhanced sensing sensitivity; collaboration on quantum sensing with color centers; (2) Plasmonic nanocavities — few-nm gap junctions enhance Raman scattering by ×10^9, enabling single-molecule vibrational spectroscopy and coherent control; ultrafast and single-photon detection of coherent phonon dynamics; (3) 2D heterostructure photonics — entangled photon pair generation enhanced by TMD heterostructures; valley-polarized exciton sources; (4) Optical frequency conversion for quantum applications. SNSF-funded professor, internationally recognized for molecular optomechanics and carbon nanotube quantum optics.

Department(s)/lab(s): Materials | Photonic Nanomaterials Group @ Oxford
Summary:

Smith leads the Photonic Nanomaterials Group, studying nanostructured materials (semiconductor nanocrystals, diamond colour centres) coupled to open-access tunable optical microcavities, with applications spanning efficient spin-photon interfaces for NV-diamond quantum networks and single-photon sources.

Department(s)/lab(s): Electrical Engineering | Vuckovic Nanoscale and Quantum Photonics Lab @ Stanford
Summary:

Vuckovic's lab uses inverse-designed nanophotonic cavities and waveguides to couple diamond (NV/SiV) and other solid-state spin defects to light, building integrated quantum photonic devices for quantum sensing, networking, and single-photon sources.