Technique - (3) Nanofibre-trapped cold atom interface

Type: Experimental

Description: Trapping laser-cooled atoms around tapered optical nanofibres for strong light-matter coupling.

Department(s)/lab(s): Physics / Niels Bohr Institute | Copenhagen Center for Biomedical Quantum Sensing (CBQS) @ UCPH
Summary:

Jean-Baptiste Béguin's research at QUANTOP centers on optical nanofibre-trapped atom interfaces for quantum memories and quantum networks. Research: (1) nanofibre-trapped cold Cs atoms — quantum noise spectroscopy of atom-light spin coupling; (2) single-photon storage and retrieval from nanofibre-guided modes; (3) sub-Poissonian atom loading. Key direction in CBQS center for quantum sensing via coherent atom-photon interfaces.

Department(s)/lab(s): Physics / LKB | Quantum Networks Group (Laurat Lab) @ ENS Paris
Summary:

Julien Laurat's quantum networks group develops atomic interfaces for long-distance quantum communication and sensing. Research: (1) cold atom quantum memory using DLCZ-protocol and EIT — multi-mode storage, entanglement generation; (2) nanofibre-trapped atom light interface for quantum networks; (3) quantum memory for telecom-band photons using rare-earth crystals. CNRS Silver Medal 2026. ERC Consolidator grant. Highly relevant to quantum sensing via atomic sensors and quantum network nodes.

Department(s)/lab(s): Physics / Niels Bohr Institute | Quantum Metrology Group (Müller Lab) @ UCPH
Summary:

Jörg Müller's Quantum Metrology group works on next-generation optical atomic clocks and superradiant lasers. Key experiments: cold strontium continuous superradiant laser (subnatural linewidth, pushing beyond traditional clock limitations); microresonator-based frequency combs; ultra-stable optical reference cavities; and cavity QED many-atom systems for clocks and sensing. The group is part of the EU iqClock project targeting operational optical lattice clocks.