Research Areas - (9) GNOME Global Magnetometer Network

Full path: Physics > Quantum Sensing > Magnetometry (OPM, SERF, etc.) > GNOME Global Magnetometer Network

Department(s)/lab(s): Department of Physics | Derevianko Group @ UNR
Summary:

Derevianko is a theorist in precision AMO physics - atomic parity violation, atomic clocks, and theory/analysis of dark-matter searches with global networks of precision quantum sensors (clocks and magnetometers). The work complements NV-center diamond ensemble quantum sensing (DEER, NMR, T1 relaxometry) at pT/sqrt(Hz) sensitivity by pursuing the same field-sensing goals in a different physical platform.

Department(s)/lab(s): M. Smoluchowski Institute of Physics | Photonics / Atomic Optics @ Jagiellonian
Summary:

Gawlik works on nonlinear magneto-optics and atomic magnetometry (NMOR, NV-diamond magnetometry) and contributes to the GNOME network. This vapour-phase approach reaches femto-to-picotesla sensitivities complementary to NV-center diamond ensemble quantum sensors (DEER, nano-NMR, T1 relaxometry) that operate near the pT/sqrt(Hz) regime.

Department(s)/lab(s): Department of Physics | Jackson Kimball Lab @ CSUEB
Summary:

Jackson Kimball uses atomic magnetometry (including SERF and nonlinear magneto-optical rotation) for tests of fundamental symmetries and ultralight dark-matter searches; he co-leads GNOME and contributes SERF magnetometry to CASPEr. This vapour-phase approach reaches femto-to-picotesla sensitivities complementary to NV-center diamond ensemble quantum sensors (DEER, nano-NMR, T1 relaxometry) that operate near the pT/sqrt(Hz) regime.

Department(s)/lab(s): Twinleaf LLC | Twinleaf @ Twinleaf
Summary:

Kornack (from Romalis's Princeton group) founded Twinleaf, which builds atomic magnetometers, alkali-noble-gas SERF comagnetometers and low-noise magnetic shielding/coils used across fundamental-physics and sensing experiments. This vapour-phase approach reaches femto-to-picotesla sensitivities complementary to NV-center diamond ensemble quantum sensors (DEER, nano-NMR, T1 relaxometry) that operate near the pT/sqrt(Hz) regime.

Department(s)/lab(s): M. Smoluchowski Institute of Physics | Optical Magnetometry group @ Jagiellonian
Summary:

Pustelny leads Krakow's optical-magnetometry group, developing atomic magnetometers, zero-field NMR and running/analysing the GNOME dark-matter network. This vapour-phase approach reaches femto-to-picotesla sensitivities complementary to NV-center diamond ensemble quantum sensors (DEER, nano-NMR, T1 relaxometry) that operate near the pT/sqrt(Hz) regime.

Department(s)/lab(s): Department of Physics and Astronomy | Stalnaker Lab @ Oberlin
Summary:

Stalnaker runs an atomic-vapour magnetometry and direct frequency-comb spectroscopy lab and is a node of the GNOME network searching for exotic-field and dark-matter transients. This vapour-phase approach reaches femto-to-picotesla sensitivities complementary to NV-center diamond ensemble quantum sensors (DEER, nano-NMR, T1 relaxometry) that operate near the pT/sqrt(Hz) regime.

Department(s)/lab(s): Department of Physics and Astronomy | Sulai Lab @ Bucknell
Summary:

Sulai works on atomic magnetometry and precision measurement, contributing to the GNOME network and analysis of correlated exotic-physics signals. This vapour-phase approach reaches femto-to-picotesla sensitivities complementary to NV-center diamond ensemble quantum sensors (DEER, nano-NMR, T1 relaxometry) that operate near the pT/sqrt(Hz) regime.

Department(s)/lab(s): Department of Physics | Physics of Atomic Media (FRAP) @ Fribourg
Summary:

Weis pioneered optically pumped alkali-vapour magnetometry (double-resonance, magneto-optical) with applications to biomagnetism and fundamental physics; FRAP is a founding GNOME node. This vapour-phase approach reaches femto-to-picotesla sensitivities complementary to NV-center diamond ensemble quantum sensors (DEER, nano-NMR, T1 relaxometry) that operate near the pT/sqrt(Hz) regime.

Department(s)/lab(s): Institute of Physics / Helmholtz Institute Mainz | Budker Group (Matter-Antimatter section) @ JGU
Summary:

Wickenbrock develops atomic magnetometry and zero-to-ultralow-field NMR for chemical analysis and fundamental-physics searches (CASPEr, GNOME), including diamond- and OPM-based ZULF detection. This vapour-phase approach reaches femto-to-picotesla sensitivities complementary to NV-center diamond ensemble quantum sensors (DEER, nano-NMR, T1 relaxometry) that operate near the pT/sqrt(Hz) regime.