Constrained minimal-interface structures in polycrystalline copper with extremely fine grains

Li, X. Y.; Jin, Zhaohui; Zhou, Xinzhe; Lu, K.

doi:10.1126/science.abe1267

Cited by 99 publications

(56 citation statements)

References 47 publications

(45 reference statements)

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“…For the last case, consider a nano-scaled grain growth process under tensile stress. The nano-grained metals have attracted great attention due to their excellent properties for the structure designed [29,30]. Since the grain growth process is widely simulated Another advantage of exchange coupled composites is that the structure is easy to be designed for better performance.…”

Section: Simulation Resultsmentioning

confidence: 99%

Lattice Phase Field Model for Nanomaterials

Liang

2021

Materials

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The lattice phase field model is developed to simulate microstructures of nanoscale materials. The grid spacing in simulation is rescaled and restricted to the lattice parameter of real materials. Two possible approaches are used to solve the phase field equations at the length scale of lattice parameter. Examples for lattice phase field modeling of complex nanostructures are presented to demonstrate the potential and capability of this model, including ferroelectric superlattice structure, ferromagnetic composites, and the grain growth process under stress. Advantages, disadvantages, and future directions with this phase field model are discussed briefly.

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Section: Simulation Resultsmentioning

confidence: 99%

Lattice Phase Field Model for Nanomaterials

Liang

2021

Materials

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“…As a result, stability of pure Cu increases with the decreasing grain size, as plotted in Figure 4 . The 10-nm Schwarz crystal in Cu is even stable against grain coarsening when close to the equilibrium melting point [ 24 ]. Although intensive boundary relaxation can be triggered by rapid heating [ 30 ], deformed grains of about 70 nm in size show the worst stability and grain coarsening occurs when annealed at temperature lower than 0.3 T m .…”

Section: Resultsmentioning

confidence: 99%

“…Further refining lamellae below the saturation size is challenging due to the increasing tendency of GB annihilation via dislocation annihilation and migration of GBs during straining [ 20 ]. By increasing strain rates and/or decreasing deformation temperature, grains of pure Cu can be refined to 40 nm [ 21 , 22 , 23 ] and even down to 10 nm [ 24 ]. However, the nanostructured Cu tends to show morphology of roughly equiaxed grains with plenty of twins and stacking faults rather than laminated structure as that in Ni [ 1 , 11 ] and Al [ 5 ].…”

Section: Introductionmentioning

confidence: 99%

Formation of Nanolaminated Structure with Enhanced Thermal Stability in Copper

Hou

2021

Nanomaterials

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Nanolaminated structure with an average boundary spacing of 67 nm has been fabricated in copper by high-rate shear deformation at ambient temperature. The nanolaminated structure with an increased fraction of low angle grain boundaries exhibits a high microhardness of 2.1 GPa. The structure coarsening temperature is 180 K higher than that of its equiaxial nanograined counterpart. Formation of nanolaminated structure provides an alternative way to relax grain boundaries and to stabilize nanostructured metals with medium to low stacking faults energies besides activation of partial dislocations.

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“…Fig. 3 | Structural evolution of the p-GBs in 2D MoSe2 . a, Proposed migrations of polygons along the p-GBs.…”

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confidence: 99%

“…The average grain size and microstructures of the GBs are critical to material properties. Elemental and alloyed metals can exhibit greatly enhanced yield strength by optimizing grain sizes and boundaries [1][2][3] , while strong covalent crystals can be continuously hardened by decreasing grain sizes down to a few nanometers [4][5][6] . The GB effects become more significant in two-dimensional (2D) materials [7][8][9] , where the crystalline order is highly vulnerable to various types of disorder and can be directly disrupted by a line defect.…”

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confidence: 99%

‘Colorful’ Polyline Grain Boundaries in Two-dimensional Transition Metal Dichalcogenides

Zhu

et al. 2021

Preprint

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Grain boundaries (GBs) are vital to crystal materials and their applications. Although the GBs in bulk and two-dimensional materials have been extensively studied, the polyline GBs prevalently forming in transition metal dichalcogenide monolayers by a sequence of folded segments remain a mystery. We visualize the large-area distribution of the polyline GBs in MoSe2 monolayers by means of a strain mapping method and unravel their structural origin using ab initio calculations combined with high-resolution atomic characterizations. Unlike normal GBs in two-dimensional materials with one type of dislocation cores, the polyline GBs consist of two basic elements—4|8 and 4|4|8 cores, whose alloying results in structural diversity and distinctly high stability due to relieved stress fields nearby. The defective polygons can uniquely migrate along the polyline GBs via the movement of single molybdenum atoms, unobtrusively giving the GBs their chameleon-like ‘colorful’ appearances. Furthermore, the polyline GBs can achieve useful functionalities such as intrinsic magnetism and highly active electrocatalysis.

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Constrained minimal-interface structures in polycrystalline copper with extremely fine grains

Cited by 99 publications

References 47 publications

Lattice Phase Field Model for Nanomaterials

Lattice Phase Field Model for Nanomaterials

Formation of Nanolaminated Structure with Enhanced Thermal Stability in Copper

‘Colorful’ Polyline Grain Boundaries in Two-dimensional Transition Metal Dichalcogenides

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