Unique grain-boundary mediated plasticity: Deep Potential MD insights in HCP zinc

Weiyao Liang; Jianfeng Jin; Xiaojia Ma; Yuping Ren; Gaowu Qin

doi:10.20517/microstructures.2025.157

Microstructures ›› 2026, Vol. 6 ›› Issue (3) -2026053. DOI: 10.20517/microstructures.2025.157

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Unique grain-boundary mediated plasticity: Deep Potential MD insights in HCP zinc

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Abstract

Zinc (Zn) alloys are promising candidates for biodegradable medical applications. Their in-service performance depends critically on mechanical properties, particularly strain hardening/softening driven by grain boundary (GB) characteristics. Since the c/a ratio of hexagonal close-packed (HCP) Zn exceeds 1.8, classical interatomic potentials fail to accurately capture GB energetics and structures. In this work, a machine-learning Deep Potential (DP) model for Zn was developed. Using DP molecular dynamics (DeePMD), the energetics and structures of $ {<}11 \overline{2} 0{>} $ symmetrical tilt grain boundaries were analyzed across the full range of tilt angles (2θ = 0°~180°). Two distinct energy plateaus with minor oscillations were observed for 2θ in the ranges of 10°~90° and 96°~170°. Subsequently, DeePMD tensile simulations on the $ {<}11 \overline{2} 0{>} $ columnar grained (2D) Zn were performed to link GB energetics to plastic responses, revealing that grain rotation is the dominant plastic mechanism, facilitated by the observed energy plateaus and accompanied by limited basal dislocation activity. This grain-rotation-mediated plasticity was further confirmed by DeePMD in nanopolycrystalline (3D) Zn under tension, distinct from HCP Mg (c/a ≈ 1.63), which is dominated by multi-mode dislocations and twinning, and Be (c/a ≈ 1.52), where basal dislocations prevail. These findings highlight GB features as critical factors controlling plasticity and provide a theoretical foundation for designing nextgeneration biomedical alloys via crystallographic tailoring.

Keywords

Zinc / machine-learning potential / grain boundary / molecular dynamics / plastic mechanisms

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Weiyao Liang, Jianfeng Jin, Xiaojia Ma, Yuping Ren, Gaowu Qin. Unique grain-boundary mediated plasticity: Deep Potential MD insights in HCP zinc. Microstructures, 2026, 6(3): -2026053 DOI:10.20517/microstructures.2025.157

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Zhuo X.,Wu Y.,Ju J..et al. Recent progress of novel biodegradable zinc alloys: from the perspective of strengthening and toughening J. Mater. Res. Technol. 2022 17 244 69

[2]	Liu Y.,Zeng Z.,Gong H..et al. Work softening behavior and microstructure evolution of Zn-0.12Cu-0.08Ti alloy during cold rolling J. Alloys Compd. 2025 1032 180998

[3]	Li R.,Ding Y.,Zhang H.,Wang X.,Gao Y.,Xu J.. Toward high strength and large strain hardening Zn alloys via a novel multiscale-heterostructure strategy Mater. Sci. Eng. A 2024 899 146410

[4]	Song Z.,Niu R.,Cui X..et al. Mechanism of room-temperature superplasticity in ultrafine-grained Al-Zn alloys Acta Mater. 2023 246 118671

[5]	Hou M.,Deng K.,Wang C.,Nie K.,Shi Q.. The balance between work hardening and softening behaviors of Mg-xZn-1Gd-0.2Ca-0.1Zr alloys influenced by trace Zn addition J. Alloys Compd. 2023 969 172379

[6]	Zhao L.,Xia W.,Yan H.,Chen J.,Su B.. Effects of Zn addition on dynamic recrystallization of high strain rate rolled Al-Mg sheets Met. Mater. Int. 2021 28 1264 76

[7]	Wu C.,Lin F.,Liu H..et al. Stronger and coarser-grained biodegradable zinc alloys Nature 2025 638 684 9

[8]	Bednarczyk W.,Kawałko J.,Wątroba M.,Szuwarzyński M.,Bała P.. Investigation of slip systems activity and grain boundary sliding in fine-grained superplastic zinc alloy Archiv.Civ.Mech.Eng. 2023 23 253

[9]	Cantwell P. R.,Tang M.,Dillon S. J.,Luo J.,Rohrer G. S.,Harmer M. P.. Grain boundary complexions Acta Mater. 2014 62 1 48

[10]	Wei J.,Feng B.,Ishikawa R..et al. Direct imaging of atomistic grain boundary migration Nat. Mater. 2021 20 951 5

[11]	Schweizer P.,Sharma A.,Pethö L..et al. Atomic scale volume and grain boundary diffusion elucidated by in situ STEM Nat. Commun. 2023 14 7601 PMC10663537

[12]	Zhang X.,Wang D.,Nagaumi H..et al. Accelerating the design of highly separable Fe‐containing intermetallics in Al-Si alloys via DFT calculations and experimental validation Mater. Genome Eng. Adv. 2025 3 e70008

[13]	Yang P.,Li S.,Xie H..et al. Two-dimensional interface superstructures assembled by well-ordered solute atoms J. Mater. Sci. Technol. 2023 142 253 9

[14]	Kosarev I.,Shcherbinin S.,Kistanov A.,Babicheva R.,Korznikova E.,Dmitriev S.. An approach to evaluate the accuracy of interatomic potentials as applied to tungsten Comput. Mater. Sci. 2024 231 112597

[15]	Mishin Y.. Machine-learning interatomic potentials for materials science Acta Mater. 2021 214 116980

[16]	Nie J.,Hu C.,Yan Q.,Luo J.. Discovery of electrochemically induced grain boundary transitions Nat. Commun. 2021 12 2374 PMC8062690

[17]	Behler J.. Perspective: machine learning potentials for atomistic simulations J. Chem. Phys. 2016 145 170901

[18]	Zhang L.,Han J.,Wang H.,Car R.,E W.. Deep potential molecular dynamics: a scalable model with the accuracy of quantum mechanics Phys. Rev. Lett. 2018 120 143001

[19]	Deringer V. L.,Bernstein N.,Csányi G..et al. Origins of structural and electronic transitions in disordered silicon Nature 2021 589 59 64

[20]	Zeng J.,Cao L.,Xu M.,Zhu T.,Zhang J. Z. H.. Complex reaction processes in combustion unraveled by neural network-based molecular dynamics simulation Nat. Commun. 2020 11 5713 PMC7658983

[21]

Jia W.,Wang H.,Chen M..et al. Pushing the limit of molecular dynamics with ab initio accuracy to 100 million atoms with machine learning. In SC20: International Conference for High Performance Computing, Networking, Storage and Analysis, Atlanta, GA, USA, November 9-19, 2020; IEEE: New York, NY, USA, 2020; pp 1-14

[22]	Su H.,Zheng S.,Yang Z.,Wang J.,Ye H.. Atomic-scale insights into grain boundary-mediated plasticity mechanisms in a magnesium alloy subjected to cyclic deformation Acta Mater. 2024 277 120210

[23]	Du C.,Gao Y.,Zha M.,Wang C.,Jia H.,Wang H.. Deformation-induced grain rotation and grain boundary formation achieved through dislocation-disclination reactions in polycrystalline hexagonal close-packed metals Acta Mater. 2023 250 118855

[24]	Ma Z. C.,Tang X. Z.,Mao Y.,Guo Y. F.. The plastic deformation mechanisms of hcp single crystals with different orientations: molecular dynamics simulations Materials 2021 14 733 PMC7914641

[25]	Gou W.,Shi Z. Z.,Zhu Y..et al. Multi‐objective optimization of three mechanical properties of Mg alloys through machine learning Mater. Genome Eng. Adv. 2024 2 e54

[26]	Della Ventura N. M.,Sharma A.,Cayron C..et al. Response of magnesium microcrystals to c-axis compression and contraction loadings at low and high strain rates Acta Mater. 2023 248 118762

[27]	Liu B. Y.,Zhang Z.,Liu F..et al. Rejuvenation of plasticity via deformation graining in magnesium Nat. Commun. 2022 13 1060 PMC8881527

[28]	Fang Q.,Sansoz F.. Columnar grain-driven plasticity and cracking in nanotwinned FCC metals Acta Mater. 2021 212 116925

[29]	Chang Z.,Feng L.,Xue H. T..et al. Deep-learning potential molecular dynamics study on nanopolycrystalline Al-Er alloys: effects of Er concentration, grain boundary segregation, and grain size on plastic deformation J. Chem. Inf. Model. 2025 65 3282 93

[30]	Wang H.. Molecular modeling by machine learning Math. Numer. Sin. 2021 43 , 261-78. (in Chinese).

[31]	Wu J.,Huang A.,Xie H. P..et al. Multi-scale simulation of mechanical and thermal transport properties of materials based on machine learning potential. J. Chin. Ceram. Soc. 2023, 51, 531-43. (in Chinese)

[32]	Zhang Y.,Wang H.,Chen W..et al. DP-GEN: a concurrent learning platform for the generation of reliable deep learning based potential energy models Comput. Phys. Commun. 2020 253 107206

[33]	Wang H.,Zhang L.,Han J.,E W.. DeePMD-kit: a deep learning package for many-body potential energy representation and molecular dynamics Comput. Phys. Commun. 2018 228 178 84

[34]	Kresse G.,Hafner J.. Ab initio molecular dynamics for liquid metals Phys. Rev. B. Condens. Matter 1993 47 558 61

[35]	Kresse G.,Hafner J.. Ab initio molecular dynamics for open-shell transition metals Phys. Rev. B. Condens. Matter 1993 48 13115 8

[36]	Perdew J. P.,Burke K.,Ernzerhof M.. Generalized gradient approximation made simple Phys. Rev. Lett. 1996 77 3865 8

[37]	Monkhorst H. J.,Pack J. D.. Special points for Brillouin-zone integrations Phys. Rev. B. 1976 13 5188 92

[38]	Xu C.,Tian X.,Jiang W.,Wang Q.,Fan H.. Atomistic migration mechanisms of $ [1 2 \overline{1} 0] $ symmetric tilt grain boundaries in magnesium Int. J. Plast. 2022 156 103362

[39]	Tschopp M. A.,Mcdowell D. L.. Structures and energies of Σ3 asymmetric tilt grain boundaries in copper and aluminium Philos. Mag. 2007 87 3147 73

[40]	Hirel P.. Atomsk: a tool for manipulating and converting atomic data files Comput. Phys. Commun. 2015 197 212 9

[41]	Brostow W.,Dussault J.,Fox B. L.. Construction of Voronoi polyhedra J. Comput. Phys. 1978 29 81 92

[42]	Plimpton S.. Fast parallel algorithms for short-range molecular dynamics J. Comput. Phys. 1995 117 1 19

[43]	Stukowski A.. Visualization and analysis of atomistic simulation data with OVITO-the Open Visualization Tool Modelling Simul. Mater. Sci. Eng. 2010 18 015012

[44]	Jang H.,Kim K.,Lee B.. Modified embedded-atom method interatomic potentials for pure Zn and Mg-Zn binary system Calphad 2018 60 200 7

[45]	Wang J.,Beyerlein I. J.. Atomic structures of $ [0 \overline{1} 1 0] $ symmetric tilt grain boundaries in hexagonal close-packed (HCP) crystals Metall. Mater. Trans. A. 2012 43 3556 69

[46]	Liu X.,Adams J. B.,Ercolessi F.,Moriarty J. A.. EAM potential for magnesium from quantum mechanical forces Model. Simul. Mater. Sci. Eng. 1996 4 293 303

[47]	Agrawal A.,Mishra R.,Ward L.,Flores K. M.,Windl W.. An embedded atom method potential of beryllium Model. Simul. Mater. Sci. Eng. 2013 21 085001

[48]	Nitol M. S.,Dickel D. E.,Barrett C. D.. Artificial neural network potential for pure zinc Comput. Mater. Sci. 2021 188 110207

[49]	Mei H.,Cheng L.,Chen L.,Wang F.,Li J.,Kong L.. Development of machine learning interatomic potential for zinc Comput. Mater. Sci. 2024 233 112723

[50]	Kittel C.. Introduction to solid state physics, 8th ed.; Wiley, 2004. https://www.wiley.com/en-us/Introduction+to+Solid+State+Physics%2C+8th+Edition-p-9780471415268. (accessed 2026-04-22)

[51]	Ledbetter H. M.. Elastic properties of zinc: a compilation and a review J. Phys. Chem. Ref. Data 1977 6 1181 203

[52]	Almqvist L.,Stedman R.. Phonons in zinc at 80 K J. Phys. F: Met. Phys. 1971 1 785 90

[53]	Togo A.,Tanaka I.. First principles phonon calculations in materials science Scr. Mater. 2015 108 1 5

[54]	Chaput L.,Togo A.,Tanaka I.,Hug G.. Phonon-phonon interactions in transition metals Phys. Rev. B. 2011 84 094302

[55]	Gajdoš M.,Hummer K.,Kresse G.,Furthmüller J.,Bechstedt F.. Linear optical properties in the projector-augmented wave methodology Phys. Rev. B. 2006 73 045112

[56]	Baroni S.,Giannozzi P.,Testa A.. Green’s-function approach to linear response in solids Phys. Rev. Lett. 1987 58 1861 4

[57]	Gonze X.,Lee C.. Dynamical matrices, Born effective charges, dielectric permittivity tensors, and interatomic force constants from density-functional perturbation theory Phys. Rev. B. 1997 55 10355 68

[58]	Gengor G.,Mohammed A. S. K.,Sehitoglu H.. $ {1 \overline{0} 1 2} $ Twin interface structure and energetics in HCP materials Acta Mater. 2021 219 117256

[59]	Kumar A.,Wang J.,Tomé C. N.. First-principles study of energy and atomic solubility of twinning-associated boundaries in hexagonal metals Acta Mater. 2015 85 144 54

[60]	Lu D.,Jiang W.,Chen Y..et al. DP compress: a model compression scheme for generating efficient Deep Potential models J. Chem. Theory Comput. 2022 18 5559 67

[61]	Tsuzuki H.,Branicio P. S.,Rino J. P.. Structural characterization of deformed crystals by analysis of common atomic neighborhood Comput. Phys. Commun. 2007 177 518 23

[62]	Sun H.,Singh C. V.. Temperature dependence of grain boundary excess free volume Scr. Mater. 2020 178 71 6

[63]	Wang H.,Jin J.,Wang D..et al. Energetic and structure characteristics of the $ {<}1 1 \overline{2} 0{>} $ symmetric tilt grain boundaries of beryllium: insight from atomic simulations Mater. Rep. 2025 39 , 23110178-7. (in Chinese).

[64]	Baskes M. I.,Johnson R. A.. Modified embedded atom potentials for HCP metals Model. Simul. Mater. Sci. Eng. 1994 2 147 63

[65]	Ciechan A.,Bogusławski P.. Theory of the sp-d coupling of transition metal impurities with free carriers in ZnO Sci. Rep. 2021 11 3848 PMC7884780