Hierarchical 3D Nanolayered Duplex-Phase Zr with High Strength, Strain Hardening, and Ductility.

Nanolayered, bimetallic composites are receiving increased attention due to an exceptional combination of strength and thermal stability not possible from their coarse-layered counterparts or constituents alone. Yet, due to their 2D planar, unidirectional arrangement, they are highly anisotropic, which results in limited strain hardening and ductility. Therefore, like many high-performance, ultrastrong materials of our time, they succumb to the usual strength-ductility trade-offs. Here we present the formation of a novel hierarchical microstructure, comprised of crystals consisting of 3D nanolayered α/β-Zr networks. By direct comparison with coarse-layered material of the same chemistry, we show that the unusual hierarchical 3D structure gives rise to high strain hardening, high strength, and high ductility. Using TEM analysis and hysteresis testing, we discovered that the 3D randomly oriented biphase boundaries result in progressively dispersive rather than localized slip with increasing strain. Dislocation activity in the α-Zr lamellae transitions from single slip to multislip and eventually to multimodal slip as strain increases. The diffusive slip-promoting properties of 3D layered networks can potentially invoke simultaneous high strength, strain hardening, and ductility, and reveal a new target in the microstructural design of high performance structural materials.

[1]  Xiaolei Wu,et al.  Heterogeneous materials: a new class of materials with unprecedented mechanical properties , 2017, Heterostructured Materials.

[2]  R. Sarpong,et al.  Bio-inspired synthesis of xishacorenes A, B, and C, and a new congener from fuscol† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c9sc02572c , 2019, Chemical science.

[3]  Y. F. Wang,et al.  Interface affected zone for optimal strength and ductility in heterogeneous laminate , 2018, Materials Today.

[4]  T. Polcar,et al.  Competing mechanisms on the strength of ion-irradiated Zr/Nb nanoscale multilayers: Interface strength versus radiation hardening , 2018, Scripta Materialia.

[5]  R. Valiev,et al.  Review on superior strength and enhanced ductility of metallic nanomaterials , 2018 .

[6]  M. Preuss,et al.  Investigating the thermal stability of irradiation-induced damage in a zirconium alloy with novel in situ techniques , 2018 .

[7]  Chinthaka M. Silva,et al.  Investigation of mechanical and microstructural properties of Zircaloy-4 under different experimental conditions , 2018 .

[8]  E. Clouet,et al.  Solubility in Zr-Nb alloys from first-principles , 2017, 1711.05478.

[9]  Fucheng Zhang,et al.  Effect of annealing treatment on the microstructure and mechanical properties of a duplex Zr-2.5Nb alloy , 2017 .

[10]  M. Daymond,et al.  The stability of thermodynamically metastable phases in a Zr-Sn-Nb-Mo alloy: Effects of alloying elements, morphology and applied stress/strain , 2017 .

[11]  M. Heilmaier,et al.  Coarsening kinetics of lamellar microstructures: Experiments and simulations on a fully-lamellar Fe-Al in situ composite , 2017 .

[12]  S. Yamanaka,et al.  Crystallographic analysis on atomic-plane parallelisms between bcc precipitates and hcp matrix in recrystallized Zr-2.5Nb alloys , 2017 .

[13]  A. Chiba,et al.  Refinement of lamellar structures in Ti-Al alloy , 2017 .

[14]  T. Polcar,et al.  Combined size and texture-dependent deformation and strengthening mechanisms in Zr/Nb nano-multilayers , 2017 .

[15]  S. K. Jha,et al.  Microstructural and textural evolution during hot deformation of dilute Zr-Sn alloy , 2016 .

[16]  Q. Dong,et al.  Study of microstructure and precipitates of a Zr-2.5Nb-0.5Cu CANDU spacer material , 2016 .

[17]  S. K. Jha,et al.  Tensile properties and microstructural evolution of Zircaloy-4 processed through rolling at different temperatures , 2016 .

[18]  T. Polcar,et al.  Structural and mechanical properties of γ-irradiated Zr/Nb multilayer nanocomposites , 2016 .

[19]  Fucheng Zhang,et al.  Effect of cooling process on the formation of duplex microstructure in Zr–2.3Nb alloy , 2015 .

[20]  F. Yuan,et al.  Heterogeneous lamella structure unites ultrafine-grain strength with coarse-grain ductility , 2015, Proceedings of the National Academy of Sciences.

[21]  I. Beyerlein,et al.  A study of microstructure-driven strain localizations in two-phase polycrystalline HCP/BCC composites using a multi-scale model , 2015 .

[22]  M. Demkowicz,et al.  Defect-interface interactions , 2015 .

[23]  A. Wilkinson,et al.  Prismatic, basal, and slip strengths of commercially pure Zr by micro-cantilever tests , 2015 .

[24]  I. Beyerlein,et al.  Bulk texture evolution of nanolamellar Zr–Nb composites processed via accumulative roll bonding , 2015 .

[25]  T. Polcar,et al.  Length-scale-dependent mechanical behaviour of Zr/Nb multilayers as a function of individual layer thickness , 2015 .

[26]  M. Preuss,et al.  Microstructure and texture evolution during thermomechanical processing of β-quenched Zr , 2015 .

[27]  A. Wilkinson,et al.  Prismatic , h a i basal , and h c + a i slip strengths of commercially pure Zr by micro-cantilever tests , 2015 .

[28]  S. K. Jha,et al.  Mechanical properties of Zr–2.5%Nb pressure tube material subjected to heat treatments in α + β phase field , 2014 .

[29]  I. Beyerlein,et al.  Texture evolution in two-phase Zr/Nb lamellar composites during accumulative roll bonding , 2014 .

[30]  X. Zhang,et al.  Formation of duplex microstructure in Zr–2.3Nb alloy and its plastic behaviour at various strain rates , 2014 .

[31]  Zhibo Zhang,et al.  An extraordinary enhancement of strain hardening in fine-grained zirconium , 2014 .

[32]  R. Fu,et al.  The tensile properties and fracture behavior of gradient nano-grained/coarse-grained zirconium , 2013 .

[33]  S. K. Jha,et al.  Study of microstructure, texture and mechanical properties of Zr–2.5Nb alloy pressure tubes fabricated with different processing routes , 2013 .

[34]  Weizhong Han,et al.  Design of Radiation Tolerant Materials Via Interface Engineering , 2013, Advanced materials.

[35]  I. Beyerlein,et al.  High-strength and thermally stable bulk nanolayered composites due to twin-induced interfaces , 2013, Nature Communications.

[36]  Zhibo Zhang,et al.  Simultaneously enhancing the ductility and strength of cryorolled Zr via tailoring dislocation configurations , 2012 .

[37]  Amit Misra,et al.  Effect of grain boundary character on sink efficiency , 2012 .

[38]  M. Daymond,et al.  Dislocation structure evolution induced by irradiation and plastic deformation in the Zr–2.5Nb nuclear structural material determined by neutron diffraction line profile analysis , 2012 .

[39]  F. C. Zhang,et al.  Achieving high strength and toughness in a Zr–2.3Nb alloy by the formation of duplex microstructure , 2012 .

[40]  S. Cai,et al.  Deformation of high β-phase fraction Zr–Nb alloys at room temperature , 2012 .

[41]  Jian Wang,et al.  Atomic-scale study of nucleation of dislocations from fcc–bcc interfaces , 2012 .

[42]  Zhibo Zhang,et al.  High strength and ductility in multimodal-structured Zr , 2012 .

[43]  W. Marsden I and J , 2012 .

[44]  G. Ackland Controlling Radiation Damage , 2010, Science.

[45]  Blas P. Uberuaga,et al.  Efficient Annealing of Radiation Damage Near Grain Boundaries via Interstitial Emission , 2010, Science.

[46]  K. Lu,et al.  Strengthening Materials by Engineering Coherent Internal Boundaries at the Nanoscale , 2009, Science.

[47]  S. Cai,et al.  Evolution of interphase and intergranular stresses in Zr–2.5Nb during room temperature deformation , 2009 .

[48]  M. Griffiths,et al.  The transformation behaviour of the β-phase in Zr–2.5Nb pressure tubes , 2008 .

[49]  R. Tewari,et al.  Microstructural evolution in zirconium based alloys , 2008 .

[50]  R. A. Holt In-reactor deformation of cold-worked Zr–2.5Nb pressure tubes , 2008 .

[51]  M. E. Kassner,et al.  The fabrication of bulk ultrafine-grained zirconium by accumulative roll bonding , 2007 .

[52]  Amit Misra,et al.  Length-scale-dependent deformation mechanisms in incoherent metallic multilayered composites , 2005 .

[53]  R. Hoagland,et al.  Effects of elevated temperature annealing on the structure and hardness of copper/niobium nanolayered films , 2005 .

[54]  Lei Lu,et al.  Ultrahigh Strength and High Electrical Conductivity in Copper , 2004, Science.

[55]  Tetsuo Sakai,et al.  Novel ultra-high straining process for bulk materials—development of the accumulative roll-bonding (ARB) process , 1999 .

[56]  G. Weatherly,et al.  The structure of h.c.p.–b.c.c. interfaces in aZr–Nb alloy , 1998 .

[57]  G. Purdy,et al.  A TEM study of the crystallography and interphase boundary structure of α precipitates in a Zr-2.5 wt% Nb alloy , 1993 .

[58]  G. Weatherly,et al.  The β to α transformation in a Zr-2.5 wt% Nb alloy , 1989 .

[59]  J. Embury,et al.  The structure and properties of microduplex Zr-Nb alloys , 1977 .