Achieving a remarkable low-temperature tensile ductility in a high-strength tungsten alloy 被引量：1

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摘要 Hot-swaging yields a high ultimate tensile strength of 712 MPa but a limited tensile ductility with the total elongation of3.6%at a testing temperature of 200℃in a representative W-0.5wt.%ZrC alloy.In this work,the evolution of Vickers microhardness with annealing temperatures is investigated in detail,which contributes to a rough index chart to guide the search for an optimized post-annealing temperature.Through the post-annealing around 1300℃,an outstanding tensile ductility at200℃,including a uniform elongation of 14%and a total elongation of~25%,has been achieved without the sacrifice of its strength.The evolution of dislocations and grain structures with the annealing temperatures accessed through backscattered scanning electron microscope and transmission electron microscope analysis reveals that the improved low-temperature tensile ductility has resulted from the reduction of residual dislocations and dislocation tanglement via the static recovery,which provides more room to accommodate dislocations,and hence stronger strain hardening ability and tensile ductility.

作者 Xiang Cheng Zhuo-Ming Xie Xue-Feng Xie Long-Fei Zeng Rui Liu Jun-Feng Yang Xue-Bang Wu Xian-Ping Wang Chang-Song Liu Qiang-Feng Fang

机构地区 Key Laboratory of Materials Physics University of Science and Technology of China Faculty of Materials Metallurgy and Chemistry

出处《Tungsten》 EI CSCD 2024年第1期150-161,共12页 钨科技（英文）

基金 financially supported by the National Key Research and Development Program of China (Grant Nos.2019YFE03110200,2019YFE03120001 and 2022YFE03140002) the National Natural Science Foundation of China (Grant Nos.:52173303,11735015,52171084,U1967211) an Anhui Provincial Natural Science Foundation (No.1908085J17) the Major Science and Technology Projects of Anhui Province (No.202103a05020016) a HFIPS Director’s Fund (YZJJZX202012,YZJJ202206-CX,BJPY2021A05)。

关键词 TUNGSTEN Low-temperature ductility ANNEALING Dislocations

分类号 TG146.411 [金属学及工艺—金属材料]

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