Precise magnetic field reconstruction and identification of internal and external noise sources are essential for the next generation of fundamental symmetry tests, including electric dipole moment (EDM) and Ultra-light Dark Matter (DM) searches. The HeXe2 experiment, a new spin-clock measurement using polarized 3-He and 129-Xe, sensitive to both EDMs and DM, is currently being developed. It will be based in the new magnetically shielded facility at TUM, which is funded through a 2.6 MEUR DFG grant.
To ensure that also the new generation of this experiment provides the best sensitivity in this field of research, we would like to demonstrate our new idea of 3D reconstruction of magnetic spin precession signals through an array of magnetic field sensors and advanced signal modeling methods. This will enable (i) conceptually novel insights into systematic issues of the next generation of such experiments and (ii) allow for a new method to suppress external noise sources through numerical separation of external and internal sources of signal.
The high data quality from our new approach will enable the use of new methods like AI or advanced statistical modeling and thus a concept step in this field of research. We could identify a new data acquisition unit, which can simultaneously sample 42 channels at >16-bit depth, high speeds of >100 kHz, and a GB of onboard memory while being stabilized with an atomic clock. The system is based on an enhanced version of the hardware that our group is already experienced with. To perform the project, we thus want to purchase such a new system together with several fluxgate magnetic field sensors for R&D, which also serves for optimization of the measurement environment.