To improve the yield strength of metallic materials at low temperatures,a strategy of combining the calculation of phase diagrams(CALPHAD)technique with the overall valence electron concentration(OVEC)principle is app...To improve the yield strength of metallic materials at low temperatures,a strategy of combining the calculation of phase diagrams(CALPHAD)technique with the overall valence electron concentration(OVEC)principle is applied,and a Ni_(2)CoCrNb_(0.2)medium-entropy alloy(MEA)with D022 superlattice(noted as theγ″phase)is designed.Bulk MEA samples without defects were successfully fabricated using laser additive manufacturing(AM),followed by solution treatment at 1200℃for 1 h and then aging at 650℃for 120 h.The nanoscaleγ″phase precipitated.The tensile results indicated that the MEA had superior yield strengths of∼1180 MPa and∼1320 MPa and tensile strengths of∼1335 MPa and∼1552 MPa at 293 K and 77 K,respectively.The yield strength obtained was superior to that of currently reported medium/high-entropy alloys and typical advanced cryogenic steel.The mechanical properties of the Ni_(2)CoCrNb_(0.2)MEA demonstrated a strong temperature dependence,and the increased yield strength was mainly attributed to the increase in lattice friction stress at low temperatures.This research provides a new strategy for producing materials with ultrastrong cryogenic yield strengths by AM.展开更多
基金National Natural Science Foundation of China(No.52164044)the Natural Science Foundation of Guizhou Province of China(No.2022[053])+1 种基金the Talent growth plan of Guizhou education department of China(No.[2022]137)the Plan of Key Laboratory of Advanced Manufacturing Technology of the Ministry of Education of Guizhou University,China(No.GZUAMT2021KF[12]).
文摘To improve the yield strength of metallic materials at low temperatures,a strategy of combining the calculation of phase diagrams(CALPHAD)technique with the overall valence electron concentration(OVEC)principle is applied,and a Ni_(2)CoCrNb_(0.2)medium-entropy alloy(MEA)with D022 superlattice(noted as theγ″phase)is designed.Bulk MEA samples without defects were successfully fabricated using laser additive manufacturing(AM),followed by solution treatment at 1200℃for 1 h and then aging at 650℃for 120 h.The nanoscaleγ″phase precipitated.The tensile results indicated that the MEA had superior yield strengths of∼1180 MPa and∼1320 MPa and tensile strengths of∼1335 MPa and∼1552 MPa at 293 K and 77 K,respectively.The yield strength obtained was superior to that of currently reported medium/high-entropy alloys and typical advanced cryogenic steel.The mechanical properties of the Ni_(2)CoCrNb_(0.2)MEA demonstrated a strong temperature dependence,and the increased yield strength was mainly attributed to the increase in lattice friction stress at low temperatures.This research provides a new strategy for producing materials with ultrastrong cryogenic yield strengths by AM.
