Mechanisms of Bulk Diffusion at "High" and "Low" Temperatures

A phenomenological model has been proposed for bulk self-diffusion and diffusion of interstitial atoms in the ranges of high (T > T(D)) and low (T < T(D)) temperatures (where T(D) is Debye temperature). It has been shown that the mechanisms of diffusion at high and low temperatures differ significantly. In the high-temperature range, the diffusion is provided by fluctuations, which can be described in terms of local melting, i.e., the formation of a "liquid diffusion channel." In the low-temperature range, when melting for some reasons is hindered, the diffusion is due to the fluctuation formation of a "hollow diffusion channel." The calculation of the activation energies of these processes in the case of self-diffusion agrees well with the experiment in the temperature range T > T(D) and has demonstrated that the activation energy increases significantly at T < T(D). The calculation of the activation energy for diffusion of interstitial atoms in bcc metals agrees well with the experiment in the entire temperature range and provides an explanation of the decrease in the activation energy of diffusion at low temperatures.