Void Sink Strength in H.C.P. Materials

Grande, N. Smetniansky-De; Tomé, Carlos N.; Savino, E. J.

doi:10.1002/pssb.2221670210

Cited by 11 publications

(1 citation statement)

References 27 publications

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“…Analytic expressions of d … ¶ ; ¶ 0 † for hcp metals as a function of Grande (1987) and Smetniansky-de Grande et al (1991). There is little information on the dipole tensors for point defects in hcp metals.…”

Section: } 3 Internally Pressurized Tubementioning

confidence: 99%

The effect of stress on point-defect diffusion in hcp metals and irradiation creep

H.Woo¹

2000

Philosophical Magazine A

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Crystalline materials exposed to irradiation by high-energy particles produce defects such as lattice vacancies and interstitials. If the migration properties of the vacancy and interstitial are di erent, their annihilation behaviours at di erent sinks are biased. The resulting microstructure changes lead to macroscopic deformation. In hcp metals, anisotropic di usion of the point defects is an intrinsic property related to the structure of the crystal lattice. The di usional anisotropy is changed when a stress is applied to the crystal. The intrinsic anisotropy produces irradiation growth, while the stress-induced change in the di usional anisotropy causes a deformation proportional to the applied stress, and contributes to irradiation creep. Irradiation creep due to the stress-induced change of the di usion anisotropy has been investigated extensively in the cubic but not the hcp metals. In this paper, the elastodi usion tensor of point defects in hcp metals is derived and applied to calculate the creep deformation by dislocations. The possibility that hydrostatic stress causes shear creep deformation is discussed.

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Section: } 3 Internally Pressurized Tubementioning

confidence: 99%

The effect of stress on point-defect diffusion in hcp metals and irradiation creep

H.Woo¹

2000

Philosophical Magazine A

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Dipole Tensors and Volume Changes of Point Defects in H.C.P. Lattices

Monti¹

1991

Physica Status Solidi (b)

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By computer simulation techniques dipole tensors and relaxation volumes of point defects in h.c.p. lattices are calculated for the fully relaxed lattice. Short‐range pair interatomic potentials to represent Mg and α‐Zr are used. Calculations for the vacancy at its equilibrium and activated states are reported. Quantitative differences due to the material elastic properties are found. For self interstitials, dipole tensor symmetries and volume‐change values are analyzed taking into account the defect‐lattice symmetries.

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