Spinodal Decomposition Stabilizes Plastic Flow in a Nanocrystalline Cu-Ti Alloy

AMI: Acta Materialia Pub Date : 2021-02-19 DOI:10.2139/ssrn.3793931
J. Rosalie, O. Renk, R. Pippan
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引用次数: 1

Abstract

A combination of high strength and reasonable ductility has been achieved in a copper-1.7 at.%titanium alloy deformed by high-pressure torsion. Grain refinement and a spinodal microstructure provided a hardness of 254 ± 2 Hv, yield strength of 800 MPa and elongation of 10%. The spinodal structure persisted during isothermal ageing, further increasing the yield strength to 890MPa while retaining an elongation of 7%. This work demonstrates the potential for spinodal microstructures to overcome the difficulties in retaining ductility in ultra-fine grained or nanocrystalline alloys, especially upon post- deformation heating where strain softening normally results in brittle behavior.
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纳米晶Cu-Ti合金的自旋分解稳定塑性流动
在铜-1.7合金中实现了高强度和合理延展性的结合。%高压扭转变形的钛合金。晶粒细化和纵向组织使其硬度为254±2 Hv,屈服强度为800 MPa,延伸率为10%。等温时效过程中,合金的屈服强度达到890MPa,延伸率为7%。这项工作表明,spinodal显微组织有潜力克服在超细晶或纳米晶合金中保持延展性的困难,特别是在变形后加热时,应变软化通常会导致脆性行为。
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AMI: Acta Materialia
AMI: Acta Materialia
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