More Like this

1. The role of embedded coordinates for disclinations and disconnection components

   https://doi.org/10.1016/j.actamat.2024.119887  

   Hirth, John P; Wang, Jian (June 2024, Acta Materialia)

   The standard model is applied for partial disclination pairs in hard materials. These defects comprise two partial disclinations and an intervening fault that can be a twin boundary, grain boundary or interphase boundary. In three dimensions there are six types. Two of them can be considered Somigliana disclinations. The standard model includes geometrically nonlinear embedded coordinates. It entails partitioning of displacements that result in configurations and strain fields not considered classically for partial disclinations. These concepts are applied to boundary junctions, disconnections, and multiple twins. Recovered stress-free structures are considered. 

   more » « less
2. Grain rotation mechanisms in nanocrystalline materials: Multiscale observations in Pt thin films

   https://doi.org/10.1126/science.adk6384  

   Tian, Yuan; Gong, Xiaoguo; Xu, Mingjie; Qiu, Caihao; Han, Ying; Bi, Yutong; Estrada, Leonardo Velasco; Boltynjuk, Evgeniy; Hahn, Horst; Han, Jian; et al (October 2024, Science)

   Near-rigid-body grain rotation is commonly observed during grain growth, recrystallization, and plastic deformation in nanocrystalline materials. Despite decades of research, the dominant mechanisms underlying grain rotation remain enigmatic. We present direct evidence that grain rotation occurs through the motion of disconnections (line defects with step and dislocation character) along grain boundaries in platinum thin films. State-of-the-art in situ four-dimensional scanning transmission electron microscopy (4D-STEM) observations reveal the statistical correlation between grain rotation and grain growth or shrinkage. This correlation arises from shear-coupled grain boundary migration, which occurs through the motion of disconnections, as demonstrated by in situ high-angle annular dark-field STEM observations and the atomistic simulation–aided analysis. These findings provide quantitative insights into the structural dynamics of nanocrystalline materials. 

   more » « less
3. Modeling of experimentally observed topological defects inside bulk polycrystals

   https://doi.org/10.1088/1361-651X/acff7c  

   Singh, Siddharth; Liu, He; Arora, Rajat; Suter, Robert M.; Acharya, Amit (October 2023, Modelling and Simulation in Materials Science and Engineering)

   Abstract A rigorous methodology is developed for computing elastic fields generated by experimentally observed defect structures within grains in a polycrystal that has undergone tensile extension. An example application is made using a near-field high energy x-ray diffraction microscope measurement of a zirconium sample that underwent $13.6\mathrm{\%}$tensile extension from an initially well-annealed state. (Sub)grain boundary features are identified with apparent disclination line defects in them. The elastic fields of these features identified from the experiment are calculated. 

   more » « less
4. Elongation and percolation of defect motifs in anisotropic packing problems

   https://doi.org/10.1039/d0sm02174a  

   Xie, Zhaoyu; Atherton, Timothy J. (April 2021, Soft Matter)

   null (Ed.)

   We examine the regime between crystalline and amorphous packings of anisotropic objects on surfaces of different genus by continuously varying their size distribution or shape from monodispersed spheres to bidispersed mixtures or monodispersed ellipsoidal particles; we also consider an anisotropic variant of the Thomson problem with a mixture of charges. With increasing anisotropy, we first observe the disruption of translational order with an intermediate orientationally ordered hexatic phase as proposed by Nelson, Rubinstein and Spaepen, and then a transition to amorphous state. By analyzing the structure of the disclination motifs induced, we show that the hexatic-amorphous transition is caused by the growth and connection of disclination grain boundaries, suggesting this transition lies in the percolation universality class in the scenarios considered. 

   more » « less
5. Topological model of type II deformation twinning in 10M Ni-Mn-Ga

   https://doi.org/10.1016/j.actamat.2020.10.020  

   Karki, Bibek; Müllner, Peter; Pond, Robert C.The (October 2020, Acta materialia)

   null (Ed.)

   The structure of type II twins in 10M Ni-Mn-Ga is modeled using the topological method. This method predicts the same twinning parameters as the kinematic model of Bevis and Crocker. Furthermore, topological modeling provides mechanistic insight into boundary migration rates, the twinning stresses and their temperature dependence. A type II twin is envisaged to form from a precursor, which is its type I conjugate. Disconnections on the precursor k_1 plane align into a tilt wall, which, after the relaxation of the rotational distortions, forms the type II boundary parallel on average to the k_2 plane. The component defects may align into a sharp wall or relax by kinking into a less orderly configuration. Both interfaces can host additional glissile disconnections whose motion along a boundary produces combined migration and shear. The ease of motion of these defects increases with their core width, and this, in turn, decreases with increasing sharpness of the boundary. Some experimental evidence in other materials suggests that type II twins can reduce their interfacial energy by adopting a configuration of low-index facets, which reduces twin boundary mobility. Topological modeling suggests that such a coherently faceted structure is unlikely in 10M Ni-Mn-Ga, in agreement with the high mobility of type II twin boundaries. 

   more » « less