Summary
Field-SEER will develop magnetic sensors with combined spatial, temporal, and field resolution beyond what is possible with existing sensing approaches. The “energy resolution” of a sensor describes this combined performance, and determines a sensor’s ability to detect weak, localized and transient signals. In today’s best-developed sensors, the energy resolution is known to be limited by a combination of intrinsic quantum noise and self-interaction effects. Field-SEER will develop sensors that evade such limits, and in doing so establish a new paradigm for extreme field sensing. The immediate fruits of this new approach will be sensors for two exceptionally demanding contemporary applications: First, a spinor Bose-Einstein condensate co-magnetometer will be developed to search for short-range forces predicted by several models of physics beyond the standard model. Second, optically-addressed nuclear spin ensembles will be developed as high-density vapor-phase magnetometers for next-generation magnetic brain imaging. In both cases, orders-of-magnitude improvement are predicted both for the energy resolution and for application-specific metrics. Field-SEER will also study how spin squeezing, predicted to play an important role in these sensors due to their extraordinary coherence properties, can be harnessed for optimal sensing in this new regime of exceptional energy resolution.
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Web resources: | https://cordis.europa.eu/project/id/101097313 |
Start date: | 01-01-2024 |
End date: | 31-12-2028 |
Total budget - Public funding: | 2 402 831,00 Euro - 2 402 831,00 Euro |
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Original description
Field-SEER will develop magnetic sensors with combined spatial, temporal, and field resolution beyond what is possible with existing sensing approaches. The “energy resolution” of a sensor describes this combined performance, and determines a sensor’s ability to detect weak, localized and transient signals. In today’s best-developed sensors, the energy resolution is known to be limited by a combination of intrinsic quantum noise and self-interaction effects. Field-SEER will develop sensors that evade such limits, and in doing so establish a new paradigm for extreme field sensing. The immediate fruits of this new approach will be sensors for two exceptionally demanding contemporary applications: First, a spinor Bose-Einstein condensate co-magnetometer will be developed to search for short-range forces predicted by several models of physics beyond the standard model. Second, optically-addressed nuclear spin ensembles will be developed as high-density vapor-phase magnetometers for next-generation magnetic brain imaging. In both cases, orders-of-magnitude improvement are predicted both for the energy resolution and for application-specific metrics. Field-SEER will also study how spin squeezing, predicted to play an important role in these sensors due to their extraordinary coherence properties, can be harnessed for optimal sensing in this new regime of exceptional energy resolution.Status
SIGNEDCall topic
ERC-2022-ADGUpdate Date
12-03-2024
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