Tags - (4) atomic vapour magnetometry OPM

Department(s)/lab(s): Engineering | FEMTO-ST - Time-Frequency Department, Atomic Clocks Group @ CNRS
Summary:

Boudot has been a permanent CNRS researcher in the Time-Frequency department of FEMTO-ST since 2008, developing compact and miniaturized atomic clocks based on coherent population trapping (CPT) in cesium vapor microcells, including all-optical, cavity-free designs that remove the traditional microwave cavity to shrink clock volume toward chip scale for GNSS, telecom and potential deep-sea seismic-sensing deployment. He received the EFTF Young Scientist Award in 2020 for this work.

Department(s)/lab(s): Physics | 5th Institute of Physics (Pfau Group) @ Stuttgart
Summary:

Pfau's institute spans dipolar quantum gases (first Dy BEC, supersolids), interacting Rydberg atoms for simulation/computing, Rydberg electrometry with thermal atomic vapours and integrated atomic photonics, and laser cooling of molecules. Rydberg vapour electrometry is a leading electric-field quantum sensor. In the broader landscape of NV-centre ensemble quantum sensing (DEER, nano-NMR, T1 relaxometry) operating near pT/sqrt(Hz) sensitivity, this work complements spin sensing with atom-based electric-field metrology.

Department(s)/lab(s): Physics | Romalis Group @ Princeton
Summary:

Romalis develops ultra-sensitive alkali-vapor magnetometers operating in the spin-exchange-relaxation-free (SERF) regime, K-noble-gas nuclear spin co-magnetometers used as gyroscopes and for electron/nuclear EDM and Lorentz-violation searches, and Rydberg-atom microwave electric-field sensors; his group's SERF magnetometers were the first used to detect brain magnetic fields. This continues and extends the historical arc of atomic and NV-ensemble quantum sensing (comparable in spirit to DEER/NMR/T1-relaxometry approaches reaching pT/sqrt(Hz) sensitivities), pushing scalar and vector magnetometry toward the fT/sqrt(Hz) and below regime through spin-squeezing and multi-pass optical cells.

Department(s)/lab(s): Physics / QET Labs | GECKO Group (Weidner Lab) @ Bristol
Summary:

Carrie Weidner's GECKO group develops experimental quantum sensing and simulation with cold atoms and hot atomic vapours. Key directions: (1) robust atom interferometry for 6-axis inertial sensing using optical lattice potentials (EPSRC-funded, Infleqtion partnership); (2) magnetic field imaging with squeezed light in hot atom vapour cells (wide-field OPM-type sensing using Faraday rotation); (3) quantum optimal control theory for atom interferometric sensors. The group is establishing a full ultracold atom apparatus for quantum simulation and sensing. Active postdoc positions.