Speaker
Description
From dark matter and dark energy, to neutrino oscillations and the lack of antimatter in the universe, there is growing evidence that the Standard Model is incomplete. Tests of Quantum Electrodynamics (QED) with few-electron systems offer a promising avenue for looking for new physics, as QED is the best understood quantum field theory and extremely precise predictions can be obtained for few-electron systems. Unfortunately, despite decades of effort, QED is poorly tested in the regime of strong coulomb fields, precisely the region where new exotic physics may be most visible. I will present a new paradigm for probing higher-order QED effects using spectroscopy of Rydberg states in exotic atoms, where orders of magnitude stronger field strengths can be achieved while nuclear uncertainties may be neglected [1]. Such tests are now possible due to the advent of quantum sensing microcalorimeter x-ray detectors [2] and new facilities providing low-energy intense beams of exotic particles for precision physics. First measurements have been successfully conducted at J-PARC with muonic atoms [3], but antiprotonic atoms offer the highest sensitivity to strong-field QED. I will present an overview of the PAX project, a new experiment for antiprotonic atom x-ray spectroscopy with a large-area transition edge sensor (TES) x-ray detector at the ELENA facility at CERN. I will present the first results from the test-beam measurements for PAX conducted in 2025, show the first experimental spectra for antiprotonic atoms obtained with a TES detector, and discuss the next steps to improve the precision of the technique. Finally, the experimental paradigm can also be reversed such to study low-lying states and access nuclear properties, such as those pursued in the QUARTET collaboration at Paul Scherrer Institute to improve the charge radii of light nuclei [4]. I will present new results from QUARTET, and discuss synergies between atomic and nuclear physics accessible with these experiments. 1] N. Paul et al, Physical Review Letters 126, 173001 (2021). [2] J. Ullom and D. Bennett, Superconductor Science and Technology 28, 8 (2015). [3] T. Okumura et al, Physical Review Letters 30, 173001 (2023). [4] B. Ohayon et al, Physics 6, 206 (2024).
