Tags - (12) Rydberg atoms

Department(s)/lab(s): Physics – Laboratoire Kastler Brossel (ENS / CollΓ¨ge de France site) | Cavity QED / Circular Rydberg Atom Group (Brune/Raimond, LKB at CollΓ¨ge de France) @ Sorbonne
Summary:

Brune leads the Circular Rydberg Atom / Cavity QED group at LKB (Collège de France site), continuing the work of Serge Haroche (Nobel 2012). Note: Brune is employed by ENS, not Sorbonne Université; postdoc contracts are typically ENS/CNRS. Research directions: (1) Circular Rydberg atoms — atoms in extremely high principal quantum number states (n~50) with extremely long radiative lifetimes (~30 ms) and large dipole moments; (2) Cavity QED quantum sensing — single circular atoms probe the microwave field in a superconducting cavity photon-by-photon via quantum non-demolition measurement; (3) Quantum state engineering — generating Fock states, Schrâdinger cat states, and entangled atom-field states in the cavity; (4) Tests of quantum complementarity — observing decoherence of mesoscopic superpositions in real time as a probe of quantum-to-classical transition. The 'quantum radio receiver' using single atoms to sense individual microwave photons is a landmark quantum sensing demonstration.

Department(s)/lab(s): Physics & Astronomy – AMOPP | Molecular Quantum Matter Lab (Caldwell Group) @ UCL
Summary:

Caldwell is a Royal Society University Research Fellow establishing the Molecular Quantum Matter Lab at UCL. Research directions: (1) Precision molecular spectroscopy for dark matter and fifth-force searches β€” measuring isotope shifts in molecular systems to test Standard Model predictions and probe new forces between neutrons and electrons; (2) Quantum control of molecules in external fields β€” laser cooling, Stark deceleration, and magneto-optical trapping of polar molecules; (3) Molecular beam spectroscopy with frequency comb referencing for ultra-high-precision lineshape measurements. The lab aims to build the most precise molecular spectrometer for BSM physics searches. Actively building the lab and seeking motivated students/postdocs.

Department(s)/lab(s): Physics (LKB) | Rydberg Atoms Team @ ENS Paris
Summary:

Dotsenko is a permanent member of LKB's Rydberg-atom cavity-QED team (successor to Haroche/Brune's circular-Rydberg-atom programme), using long-lived circular Rydberg states strongly coupled to microwave photons in high-Q cavities for quantum non-demolition measurement, entanglement generation, and microwave-photon-number quantum sensing.

Department(s)/lab(s): Physics | LKB - Rydberg Atoms Team @ CNRS
Summary:

Gleyzes is a CNRS researcher in the Rydberg Atoms team at LKB (successor to Serge Haroche's cavity-QED group), where he achieved the first quantum non-demolition detection of a single microwave photon. The team now prepares non-classical states of circular Rydberg atoms as probes for electric- and magnetic-field sensing below the standard quantum limit, uses quantum optimal control to navigate large Rydberg Hilbert spaces, and has demonstrated millisecond-lived circular states at room temperature, a route toward practical Rydberg-atom quantum sensors and simulators.

Department(s)/lab(s): Physics & Astronomy – AMOPP | Hogan Group (Rydberg Atoms and Molecules) @ UCL
Summary:

Hogan's group studies atoms and molecules in high Rydberg states for precision measurements and quantum sensing. Research directions: (1) Rydberg atom electric field sensing β€” Rydberg atoms exhibit enormous electric polarizabilities; Stark-map and EIT-based electrometry with sub-mV/cm sensitivity and GHz-range frequency coverage; (2) Rydberg molecule spectroscopy β€” long-range Rydberg molecules as probes of intermolecular forces; (3) Stark deceleration and trapping of Rydberg atoms/molecules β€” producing cold samples for precision spectroscopy and scattering experiments; (4) Circular Rydberg states β€” extremely long-lived states for quantum information storage and sensing. Collaborates on quantum-enhanced sensing of RF/microwave fields.

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 & Astronomy – AMOPP | UCL Laser Cooling and Atomic Magnetometry Group (Renzoni Group) @ UCL
Summary:

Renzoni's group is internationally recognized as a pioneer in electromagnetic induction imaging (EMI) with optical atomic magnetometers. Research directions: (1) All-optical 87Rb atomic magnetometer MIT β€” demonstrated first magnetic induction tomography (MIT) with atomic magnetometers (2013), first EMI of biological tissues below the 1 Sm⁻¹ threshold (Applied Physics Letters 2020), enabling non-invasive cardiac conductivity imaging; (2) Unshielded RF atomic magnetometer operation with general regression neural network auto-optimization; (3) Non-destructive evaluation β€” industrial corrosion/defect imaging via quantum-sensitive MIT; (4) Sub-Fourier signal processing with nonlinear systems for frequency resolution beyond classical limits. Collaborates with NPL on quantum sensing standards. Applications span medicine (atrial fibrillation), security, and materials inspection.

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 | Saffman Lab (Quantum Information, Atomic Physics) @ UWMadison
Summary:

Studies neutral-atom quantum computing and quantum optics with Rydberg atoms in optical tweezer arrays, including entanglement, nonlinear optics, and Rydberg-based electrometry/sensing.

Department(s)/lab(s): Physics (LKB) | Rydberg Atoms Team @ ENS Paris
Summary:

Sayrin works on circular Rydberg-atom cavity QED at LKB, developing microwave-photon quantum-non-demolition detection and feedback-based quantum control protocols that build on the cavity-QED foundations pioneered by Haroche and Brune's team.