Nils Sandberg scite author profile

We have revealed, and resolved, an apparent inability of density functional theory, within the local density and generalized gradient approximations, to describe vacancies in Al accurately and consistently. The shortcoming is due to electron correlation effects near electronic edges and we show how to correct for them. We find that the divacancy in Al is energetically unstable and we show that anharmonic atomic vibrations explain the non-Arrhenius temperature dependence of the vacancy concentration.

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Passage of Solid Spherical Particles across the Blood‐lymph Barrier

Grotte

Juhlin

Sandberg

1960

Acta Physiologica Scandinavica

124

152

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Solid spherical particles (radius 300–700 Å) of methyl‐methacrylate marked with a fluorescent dye were administered to dogs by continuous intravenous injection in order to obtain a steady plasma concentration. Lymphatics were cannulated and lymph collected from four regions of the body: leg, liver, heart and bronchial lymphatics. The passage of particles across the blood‐lymph barrier was measured by means of simultaneous concentration measurements in blood and lymph, Particles up to 700 Å radius readily passed into liver lymph with a lymph‐plasma ratio of approximately 0.20 in the “steady state”. No measurable amounts of these particles were found in the lymph from leg, heart or bronchial lymphatics. In these regions protein molecules of “effective diffusion radii” up to 120 Å pass into lymph. If the large proteins pass by “bulk flow” through water filled pathways the size of these pathways or “capillary leaks” would lie between 120–300 Å radius.

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Modeling of chromium precipitation in Fe-Cr alloys

et al. 2004

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Systematic electronic-structure investigation of substitutional impurity diffusion and flux coupling in bcc iron

Messina

Nastar²,

Sandberg³

et al. 2016

Phys. Rev. B

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The diffusion properties of a wide range of impurities (transition metals and Al, Si, and P) in ferritic alloys are here investigated by means of a combined ab initio-atomic diffusion theory approach. The flux-coupling mechanisms and the solute-diffusion coefficients are inferred from electronic-structure calculations of solutedefect interactions and microscopic jump frequencies. All properties except the second-nearest-neighbor binding energy are found to have a characteristic bell shape as a function of the d-band filling for the 4d and 5d series, and an M shape for the 3d row because of the out-of-trend behavior of Mn. The solute jump frequencies are governed by compressibility, which makes diffusion of large solutes faster, although this effect is partially compensated for by lower attempt frequencies and larger correlations with the vacancy. Diffusion coefficients are predicted in a wide temperature range, far below the experimentally accessible temperatures. In accordance with experiments, Co is found to be a slow diffuser in iron, and the same behavior is predicted for Re, Os, and Ir impurities. Finally, flux-coupling phenomena depend on the iron jump frequencies next to a solute atom, which are mainly controlled by similar electronic interactions to those determining the binding energies. Vacancy drag and solute enrichment at sinks systematically arise below a solute-dependent temperature threshold, directly correlated with the electronic-level interactions at the equilibrium and the saddle-point states. Early transition metals with repulsive second-nearest-neighbor interactions also diffuse via vacancy drag, although they show a lower temperature threshold than the late metals. This confirms that drag is the most common solute-vacancy coupling mechanism in iron at low temperatures, and this is likely to be confirmed as well for impurity diffusion in other transition metals.

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Vacancy concentration in Al from combined first-principles and model potential calculations

et al. 2003

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Nils Sandberg

Vacancies in Metals: From First-Principles Calculations to Experimental Data

Passage of Solid Spherical Particles across the Blood‐lymph Barrier

Modeling of chromium precipitation in Fe-Cr alloys

Systematic electronic-structure investigation of substitutional impurity diffusion and flux coupling in bcc iron

Vacancy concentration in Al from combined first-principles and model potential calculations

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