📝 SummarXiv

Abstract

The rates of elastic and inelastic scattering processes of spin-polarized atomic tritium are vital inputs for the design and operation of experiments using cold, magnetically trapped tritium atoms. Elastic scattering dominates the total cross section and dictates the thermophysical properties of the vapor, determining the efficiency of magnetic evaporative cooling and the fluid dynamical properties of the trapped atom cloud. Spin-changing cross sections in both exchange and dipolar channels determine the trap lifetime of the various hyperfine states, imposing constraints on the required atomic tritium supply rate to maintain a given trap density. Motivated by the needs of next-generation spectrometers that will study the tritium beta endpoint to infer the mass of the neutrino, we present new calculations of the elastic, spin-exchange and dipolar cross sections for spin polarized atomic tritium. Cross sections and rate constants are reported for magnetic field strengths of 0-10 T and temperatures from 0-100~K in all relevant Zeeman-hyperfine channels for both tritium and hydrogen. Results are bench-marked against past calculations for atomic hydrogen and the limited available results for tritium, and extend far into the regimes where past calculations have not been available.