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This study rigorously evaluates the collisional and density effects in exotic helium atoms, specifically focusing on pionic and kaonic helium, to enhance high-precision laser spectroscopy. By employing ab initio potential energy surfaces and coupled-channel quantum scattering calculations, the authors analyze the stability of metastable states against inelastic quenching in a cryogenic helium buffer gas. The findings provide crucial theoretical reference values for pressure broadening and pressure shift coefficients, establishing benchmarks that will facilitate more accurate measurements of fundamental particle masses.
Exotic helium atoms could revolutionize precision measurements of fundamental particle masses by minimizing nuclear annihilation effects.
Exotic helium atoms act as unique atomic traps for heavy, negatively charged particles, protecting them from nuclear annihilation and nuclear capture on timescales long enough to enable high-precision laser spectroscopy. Such measurements serve as stringent tests of three-body quantum electrodynamics and offer a direct route to determining fundamental particle masses. Motivated by upcoming spectroscopic efforts targeting pionic ($\pi^{-\,4}\mathrm{He}^+$) and kaonic ($K^{-\,4}\mathrm{He}^+$) helium, we present a rigorous theoretical evaluation of the collisional and density effects governing these systems. Using an ab initio potential energy surface and coupled-channel quantum scattering calculations, we study the collisional stability of the candidate metastable states against inelastic quenching in a cryogenic helium buffer gas. Furthermore, we provide theoretical reference values for the pressure broadening and pressure shift coefficients of the targeted transitions. These results establish an essential benchmark for future experiments, paving the way for refined determinations of the pion and kaon masses.