Bulk and interface boundary diffusion in group IV hexagonal close-packed metals and alloys

Bulk and grain boundary (GB) self-diffusion and substitutional solute diffusion in group IV hexagonal close-packed (hcp) metals (alpha-Ti, alpha-Zr, and alpha-Hf) are reviewed. The recent results obtained on high-purity materials are shown to approach closely the "intrinsic" diffusion characteristics. The enhancement effect of fast-diffusing impurities (such as Fe, Ni, or Co) is discussed for both self- and substitutional bulk solute diffusion in terms of the interstitial solubility of the impurity atoms. In GB self-diffusion, the impurity effect is found to be less dramatic. The results obtained on high-purity hcp materials can be interpreted in terms of intrinsically 'normal' vacancy-mediated GB diffusion, with the ratio of GB to volume diffusion activation enthalpies of Q(gh)/Q approximate to 0.6. The GB self-diffusion in group IV hcp metals reveals distinct systematics. Bulk self-diffusion and fast interstitial solute diffusion (Fe and Ni) in the hcp phase alpha(2)-Ti3Al are reviewed. Interphase boundary diffusion of Ti in the unidirectional lamellar alpha(2)/gamma structure of the two-phase Ti48Al52 alloy is analyzed with respect to the phase boundary structure and GB self-diffusion in alpha(2)-Ti3Al.