Bourguignon studies speech and sensorimotor processing with MEG/OPM-MEG, including corticokinematic and cortico-speech coherence methods. 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.
Haueisen leads biomagnetic-source modelling and analysis and OPM-based magnetomyography/MEG, bridging bioelectromagnetism theory, instrumentation and clinical neuroscience (with the Biomagnetic Center Jena). 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.
Iivanainen develops OPM-MEG instrumentation and analysis - sensor arrays, on-scalp sampling, and source modelling (previously at Aalto). 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.
Ilmoniemi is a founder of modern MEG and TMS-EEG; he develops MEG/OPM-MEG methods, minimum-norm source estimation and multi-locus TMS neurotechnology. 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.
Jensen uses MEG/OPM-MEG to study the functional role of neuronal oscillations in attention, working memory and predictive processing, and builds OPM-MEG capability at Oxford (previously founding co-director of Birmingham's CHBH). 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.
Mullinger develops multimodal neuroimaging (simultaneous EEG-fMRI, MEG, OPM-MEG) to study neurovascular coupling, post-stimulus responses and negative BOLD, bridging electrophysiology and haemodynamics. 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.
O'Neill develops OPM-MEG analysis (movement-related interference rejection, dynamic connectivity) and naturalistic-movement paradigms such as wearable MEG during stepping. 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.
Parkkonen develops OPM-MEG instrumentation, on-scalp sensor arrays and MEG analysis methods at Aalto, the birthplace of whole-head MEG. 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.
Sander(-Thoemmes) leads PTB's optical-magnetometry group, building multi-channel OPM-MEG systems in world-class shielded rooms and studying auditory/sensory brain responses, magnetic nanoparticles and clinical applications. 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.
Seymour develops OPM-MEG interference-suppression and analysis methods and connectivity studies (formerly at UCL). 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.