ESR study of atomic hydrogen and tritium in solid T2 and T2:H2 matrices below 1K

Abstract

We report on the first ESR study of atomic hydrogen and tritium stabilized in a solid T2 and T2:H2 matrices down to 70\,mK. The concentrations of T atoms in pure T2 approached 2×1020cm-3 and record-high concentrations of H atoms 1×1020cm-3 were reached in T2:H2 solid mixtures where a fraction of T atoms became converted into H due to the isotopic exchange reaction T+H2→TH+H. The maximum concentrations of unpaired T and H atoms was limited by their recombination which becomes enforced by efficient atomic diffusion due to a presence of a large number of vacancies and phonons generated in the matrices by β-particles. Recombination also appeared in an explosive manner both being stimulated and spontaneously in thick films where sample cooling was insufficient. We suggest that the main mechanism for H and T migration is physical diffusion related to tunneling or hopping to vacant sites in contrast to isotopic chemical reactions which govern diffusion of H and D atoms created in H2 and D2 matrices by other methods.