Size-dependent geometrically necessary dislocation structures in single-crystalline tungsten

Geometrically necessary dislocations (GNDs) play a key role in accommodating strain incompatibility between neighboring grains in polycrystalline materials. One critical step toward accurately capturing GNDs in deformation models involves studying the microstructural features that promote GND accumulation and the resulting character of GND fields. This study utilizes high-resolution electron backscatter diffraction to map GND populations in a large polycrystalline sample of pure tantalum, under simple tension. A total of 1,989 grains, 3,518 grain boundaries (GBs), and 3,207 triple junctions (TJs) were examined in a subsurface region of the sample. Correlations between GND density and GB character, and to some extent, TJ character, are investigated. Statistical geometrical relationships between these entities are quantified, and also visualized, using a novel application of two-point statistics. The nature of GNDs across the sample is also visualized and assessed using a recently developed method of mapping the local net Burgers vectors. The different approaches to characterizing GND distribution are compared in terms of how they quantify the size of near boundary gradient zones.

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Character and Distribution of Geometrically Necessary Dislocations in Polycrystalline Tantalum

Hansen

Carroll

Homer

et al. 2023

Microscopy and Microanalysis

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The indentation size effect of single-crystalline tungsten revisited

Wang

Volz

Weygand

et al. 2021

Journal of Materials Research

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In this study, we have investigated the indentation size effect (ISE) of single crystalline tungsten with low defect density. As expected, the hardness shows a pronounced increase with decreasing indentation depth as well as a strong strain rate dependence. For penetration depths greater than about 300 nm, the ISE is well captured by the Nix–Gao model in the context of geometrically necessary dislocations. However, clear deviations from the model are observed in the low depth regime resulting in a bilinear effect. The hardness behavior in the low depth regime can be modeled assuming a non-uniform spacing of the geometrically necessary dislocations. We propose that the bilinear indentation size effect observed reflects the evolution of the geometrically necessary dislocation density. With increasing strain rate, the bilinear effect becomes less pronounced. This observation can be rationalized by the activation of different slip systems. Graphic abstract

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Size-dependent geometrically necessary dislocation structures in single-crystalline tungsten

Cited by 2 publications

References 32 publications

Character and Distribution of Geometrically Necessary Dislocations in Polycrystalline Tantalum

Character and Distribution of Geometrically Necessary Dislocations in Polycrystalline Tantalum

The indentation size effect of single-crystalline tungsten revisited

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