NON-LOCAL MODELING ON MACROSCOPIC DOMAIN PATTERNS IN PHASE TRANSFORMATION OF NiTi TUBES 被引量：3

NON-LOCAL MODELING ON MACROSCOPIC DOMAIN PATTERNS IN PHASE TRANSFORMATION OF NiTi TUBES

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摘要 Recent experiments revealed many new phenomena of the macroscopic domain patterns in the stress-induced phase transformation of a superelastic polycrystalline NiTi tube during tensile loading. The new phenomena include deformation instability with the formation of a helical domain, domain topology transition from helix to cylinder, domain-front branching and loading-path dependence of domain patterns. In this paper, we model the polycrystal as an elastic continuum with nonconvex strain energy and adopt the non-local strain gradient energy to account for the energy of the diffusive domain front. We simulate the equilibrium domain patterns and their evolution in the tubes under tensile loading by a non-local Finite Element Method （FEM）. It is revealed that the observed loading-path dependence and topology transition of do- main patterns are due to the thermodynamic metastability of the tube system. The computation also shows that the tube-wall thickness has a significant effect on the domain patterns： with fixed material properties and interfacial energy density, a large tube-wall thickness leads to a long and slim helical domain and a severe branching of the cylindrical-domain front. Recent experiments revealed many new phenomena of the macroscopic domain patterns in the stress-induced phase transformation of a superelastic polycrystalline NiTi tube during tensile loading. The new phenomena include deformation instability with the formation of a helical domain, domain topology transition from helix to cylinder, domain-front branching and loading-path dependence of domain patterns. In this paper, we model the polycrystal as an elastic continuum with nonconvex strain energy and adopt the non-local strain gradient energy to account for the energy of the diffusive domain front. We simulate the equilibrium domain patterns and their evolution in the tubes under tensile loading by a non-local Finite Element Method （FEM）. It is revealed that the observed loading-path dependence and topology transition of do- main patterns are due to the thermodynamic metastability of the tube system. The computation also shows that the tube-wall thickness has a significant effect on the domain patterns： with fixed material properties and interfacial energy density, a large tube-wall thickness leads to a long and slim helical domain and a severe branching of the cylindrical-domain front.

作者 Yongjun He Qingping Sun

机构地区 Department of Mechanical Engineering

出处《Acta Mechanica Solida Sinica》 SCIE EI 2009年第5期407-417,共11页 固体力学学报（英文版）

关键词 martensitic phase transition macroscopic domain patterns NiTi polycrystalline tubes non-local and nonconvex elasticity tube-wall thickness effect metastability and instability martensitic phase transition, macroscopic domain patterns, NiTi polycrystalline tubes, non-local and nonconvex elasticity, tube-wall thickness effect, metastability and instability

分类号 O4-1 [理学—物理] TK264.11 [动力工程及工程热物理—动力机械及工程]

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参考文献23

1Feng,P.and Sun,Q.P.,Experimental investigation on macroscopic domain formation and evolution in polycrystalline NiTi microtubing under mechanical force.Journal of the Mechanics and Physics of Solids,2006,54:1568-1603.
2Liakos,J.K.and Saunders,G.A.,Application of the Landau theory to elastic phase transitions.Philosophical Magazine A,1982,46:217-242.
3Bhattacharya,K.,Micrestructure of Martensite.Oxford University Press,2003.
4Ball,J.M.and James,R.D.,Proposed experimental tests of a theory of fine microstructure and the 2-well problem.Philosophical Transactions of the Royal Society of London Series A,1992,338:389-450.
5Shaw,J.A.and Kyriakides,S.,On the nucleation and propagation of phase transformation fronts in a NiTi alloy.Acta Materialia,1997,45:683-700.
6Sun,Q.P.and Li,Z.Q.,Phase transformation in superelastic NiTi polycrystalline micro-tube under tension and torsion-from localization to homogeneous deformation.International Journal of Solids and Structures,2002,39:3797-3809.
7Sun,Q.P.and He,Y.J.,A multiscale continuum model of the grain-size dependence of the stress hysteresis in shape memory alloy polycrystals.International Journal of Solids and Structures,2008,45:3868-3896.
8Sun,Q.P.,Zhao,Z.J.,Chen,W.Z.,Qing,X.L.,Xu,X.J.and Dai,F.L.,Experimental study of stress-induced localized transformation plastic zones in tetragonal zirconia polycrystalline ceramics.Journal of the American Ceramic Society,1994,77(5):1352-1356.
9uglisi,G.And Truskinovsky,L.,A mechanism of transformational plasticity.Continuum Mechanics and Thermodynamics,2002,14:437-457.
10Barsch,G.R.and Krumhansl,J.A.,Twin boundaries in ferroelastic media without interface dislocations.Physical Review Letters,1984,53:1069-1072.

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2OTUKA K, REN X. Physical metallurgy of Ti-Ni-based shape memory alloys[J]. Progress in Materials Science, 2005, 50(5): 511-678.
3ROBERTSON S W, RITCHIE R O. In vitro fatigue-crack growth and fracture toughness behavior of thin-walled superelastic Nitinol tube for endovascular stents: a basis for defining the effect of crack-like defects[J]. Biomaterials, 2007,28(4): 700-709.
4FENG P, SUN Q P. In situ profilometry for non-uniform swain field measurement of NiTi shape memory alloy microtubing under complex stress states[J]. Smart Materials and Structures, 2007, 16(1): S179-S186.
5LI Z Q. Simulation of initial formation and growth of martensitic band in NiTi micro-tube under tension[J]. International Journal of Solids and Structures, 2010, 47(1): 113-125.
6WU M H. Fabrication of nitinol materials and components[J]. Material Science Forum, 2001, 394/395: 285-292.
7TORO A, ZHOU F, WU M H, et al. Characterization of non-metallic inclusions in superelastic NiTi tubes[J]. Joumal of Materials Engineering and Performance, 2009, 18(5/6): 448-458.
8LI Z Q, SUN Q P. The initiation and growth of macroscopic martensite band in nano-grained NiTi microtube under tension[J]. International Journal of Plasticity, 2002, 18(11): 1481-1498.
9SUN Q P, LI Z Q. Phase transformation in superelastic NiTi polycrystalline micro-tubes under tension-torsion-from localization to homogeneous deformation[J]. International Journal of Solids and Structures, 2002, 39(13/14): 3797-3809.
10NG K L, SUN Q P. Stress-induced phase transformation and detwinning in NiTi polycrystalline shape memory alloy tubes[J]. Mechanics of Materials, 2006, 38(1/2): 41-56.

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2陆鹏,赵亚楠,张艳秋,江树勇.镍钛形状记忆合金管材的研究进展[J].应用科技,2013,40(3):67-74. 被引量：7
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2曾忠敏,彭向和.计及相变与塑性的NiTi形状记忆合金循环伪弹性特性描述[J].应用数学和力学,2014,35(8):850-862. 被引量：3
3Guozheng Kang,Di Song.Review on structural fatigue of NiTi shape memory alloys:Pure mechanical and thermo-mechanical ones[J].Theoretical & Applied Mechanics Letters,2015,5(6):245-254. 被引量：3
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6赵亚楠,江树勇,张艳秋,朱晓明.NiTi形状记忆合金的热变形行为及热加工图[J].应用科技,2017,44(1):76-81.
7刘俊兵.差动式形状记忆合金驱动器驱动性能研究[J].现代机械,2017(1):4-7. 被引量：4
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10康国政,阚前华,于超,宋迪.热致和磁致形状记忆合金循环变形和疲劳行为研究[J].力学进展,2018,48(1):66-147. 被引量：3

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3C.Ekiz.Metastability in the Spin-1 Blume–Emery–Griffiths Model within Constant Coupling Approximation[J].Communications in Theoretical Physics,2017,67(2):192-196.
4程涛,向宇,李健,余玲.高速冲击泡沫铝填充管的瞬态分析[J].振动与冲击,2010,29(8):81-86. 被引量：5
5梅雪松,滕立才,鲁彤,王耀明,王振超,黄龙川.放射性种子源源芯焊封工艺技术研究[J].黑龙江科学,2015,6(16):8-9. 被引量：2
6陈大岳,冯建峰,钱敏平.Metastability of exponentially perturbed Markov chains[J].Science China Mathematics,1996,39(1):7-28. 被引量：3
7孙普男,吕天全,陈辉,曹文武.Influence of Surface Transition Layers on Phase Transformation and Pyroelectric Properties of Ferroelectric Thin Film[J].Chinese Physics Letters,2008,25(9):3422-3425. 被引量：1
8庞小峰.水的非线性振动能谱的自陷理论计算[J].物理学报,1994,43(12):1987-1996. 被引量：1
9程赫明,王洪纲,谢建斌.CALCULATION OF COUPLED PROBLEM BETWEEN TEMPERATURE AND PHASE TRANSFORMATION DURING GAS QUENCHING IN HIGH PRESSURE[J].Applied Mathematics and Mechanics(English Edition),2006,27(3):305-311.
10ZHAO JiuZhou,LI HaiLi,HE Jie.The effect of the interaction between the minority phase droplets on the nucleation behavior during the liquid-liquid phase transformation[J].Science China(Physics,Mechanics & Astronomy),2007,50(4):467-471. 被引量：1

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NON-LOCAL MODELING ON MACROSCOPIC DOMAIN PATTERNS IN PHASE TRANSFORMATION OF NiTi TUBES 被引量：3

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