6533b7d6fe1ef96bd12671aa

RESEARCH PRODUCT

Theory of hydrogen and helium impurities in metals

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description

A powerful computational scheme is presented for calculating the static properties of light interstitials in metallic hosts. The method entails (i) the construction of the potential-energy field using the quasiatom concept, (ii) the wave-mechanical solution of the impurity distribution ("zero-point motion"), (iii) calculation of the forces exerted on the adjacent host atoms and their displacements, and (iv) iteration to self-consistency. We investigate self-trapping phenomena in bcc and fcc metals in detail, and calculate both the ground and low-lying excited states. Implications of the wave-mechanical or band picture to diffusion mechanisms and inelastic scattering experiments are discussed. Impurities treated are μ+, H, D, T, and He, and particular attention is paid to isotope effects among the hydrogenic impurities. It is argued that especially for μ+ and H the quantum nature of the impurity is crucial. The calculated results are in agreement with a wealth of experimental data. Peer reviewed