The concept of grain boundary engineering(GBE)has been successfully applied to L1_(2)-strengthened(CoCrNi)_(94)Al_(3)Ti_(3)medium entropy alloy,with the aim of improving the oxidation resistance by increasing the rati...The concept of grain boundary engineering(GBE)has been successfully applied to L1_(2)-strengthened(CoCrNi)_(94)Al_(3)Ti_(3)medium entropy alloy,with the aim of improving the oxidation resistance by increasing the ratio of special boundaries and suppressing discontinuous precipitation.Surprisingly,our results reveal that GBE treatment not only slows down the oxidation kinetics and but also alters the oxide scale from TiO_(2)and multi-defect Cr_(2)O_(3)to continuous and protective Cr_(2)O_(3)and Al_(2)O_(3),thereby contributing to an enhanced oxidation and anti-spalling resistance.The GBE treatment reduces the oxidation weight gain of the current alloy from 1.950 mg cm^(-2)to 1.211 mg cm^(-2)after 100 h of cyclic oxidation at 800℃.The findings show that the extensive outward diffusion of Ti accelerates ion transport and promotes microporosity,thus leading to more defects being formed in the oxide film.The GBE treatment suppresses the discontinuous precipitation of the Ti-bearing L1_(2)phase and breaks the random large angular grain boundaries network,inhibiting the diffusion of Ti and ultimately enhancing the oxidation properties of the alloy.The current work provides an idea of oxidation resistance enhancement for Ti-bearing LI_(2)-strengthened alloys without changing the alloy composition.展开更多
Precipitation-strengthened HEAs exhibit outstanding integration of strength and toughness at ambient temperature.Nevertheless,precipitates generally reduce the localized corrosion resistance in aggressive solution env...Precipitation-strengthened HEAs exhibit outstanding integration of strength and toughness at ambient temperature.Nevertheless,precipitates generally reduce the localized corrosion resistance in aggressive solution environments.To solve this problem,a strategy of introducing nano-sized L12 precipitates in CoCrFeNiAlTi HEAs has been proposed in this work.Results demonstrate the pitting corrosion potential can be elevated from 258 mVSCE to 603 mVSCE by increasing the precipitate content to 38 wt.%.Such an improvement in localized corrosion resistance can be attributed to two aspects.Firstly,L12 precipitates tend to be dissolved during the corrosion process,which promotes the heterogeneous nucleation of protective Cr2 O3 due to the rapid deposition of oxides/hydroxides of Al/Ti,and improves the passive film stability due to the Crrich FCC matrix.Secondly,the dissolution kinetic inside the pits can be suppressed on account of the enrichment of Cr element in the FCC matrix,thus inhibiting the pitting growth.In summary,the current work not only reveals the mechanisms of the nano-sized L12 precipitates upon the corrosion behavior,but also provides a strategy for designing corrosion-resistant HEA.展开更多
A heat treatment process, quenching-tempering-partitioning (Q-T-P), has been applied to a low carbon martensitic stainless steel 06Crl3Ni4Mo. By using this process, ultrafine reversed austenite can be obtained at ro...A heat treatment process, quenching-tempering-partitioning (Q-T-P), has been applied to a low carbon martensitic stainless steel 06Crl3Ni4Mo. By using this process, ultrafine reversed austenite can be obtained at room temperature. The microstructures of the reversed austenite and the martensite matrix were characterized by transmission electron microscopy (TEM) and energy dispersive spectroscopy (EDS) in detail. The results show that the ultrafine reversed austenite is enriched in Ni resulting in the austenite stability at room temperature. Two new types of nano-scale carbide precipitates are found in the martensite matrix. Detailed analysis suggests that the two nano-scale precipitates can be identified as ω phase and λ phase carbides, respectively. The orientation relationship between the ω phase and matrix is [011]α [/[2110]ω and (211)α//(0110)ω, while that between the X phase precipitate and matrix is [011]α][[0001]λ and (200)α/(1210)λ. For the present steel, the ultrafine reversed austenite and carbide precipitates obtained by Q-T-P treatment provide a good combination of high strength and toughness.展开更多
基金the National Natural Science Foundation of China(Nos.U1908219,52171163)the Key Research Program of the Chinese Academy of Sciences(No.ZDRW-CN-2021-2-2)+2 种基金the National key Research&Development Program of China(No.2022YFF0609002)the Natural Science Foundation of Liaoning Province(No.2022-BS-001)China Postdoctoral Science Foundation(No.2022M713210)。
文摘The concept of grain boundary engineering(GBE)has been successfully applied to L1_(2)-strengthened(CoCrNi)_(94)Al_(3)Ti_(3)medium entropy alloy,with the aim of improving the oxidation resistance by increasing the ratio of special boundaries and suppressing discontinuous precipitation.Surprisingly,our results reveal that GBE treatment not only slows down the oxidation kinetics and but also alters the oxide scale from TiO_(2)and multi-defect Cr_(2)O_(3)to continuous and protective Cr_(2)O_(3)and Al_(2)O_(3),thereby contributing to an enhanced oxidation and anti-spalling resistance.The GBE treatment reduces the oxidation weight gain of the current alloy from 1.950 mg cm^(-2)to 1.211 mg cm^(-2)after 100 h of cyclic oxidation at 800℃.The findings show that the extensive outward diffusion of Ti accelerates ion transport and promotes microporosity,thus leading to more defects being formed in the oxide film.The GBE treatment suppresses the discontinuous precipitation of the Ti-bearing L1_(2)phase and breaks the random large angular grain boundaries network,inhibiting the diffusion of Ti and ultimately enhancing the oxidation properties of the alloy.The current work provides an idea of oxidation resistance enhancement for Ti-bearing LI_(2)-strengthened alloys without changing the alloy composition.
基金supported by the National Natural Science Foun-dation of China(Nos.U1908219,52171163)the Key Research Program of the Chinese Academy of Sciences(No.ZDRW-CN-2021-2-2)+1 种基金the Applied Basic Research Program of Liaoning Province(grant no.2022JH2/101300005)the Central Guidance for Local Science and Technology Development Funds of Liaoning Province(grant no.2023JH6/100100016).
文摘Precipitation-strengthened HEAs exhibit outstanding integration of strength and toughness at ambient temperature.Nevertheless,precipitates generally reduce the localized corrosion resistance in aggressive solution environments.To solve this problem,a strategy of introducing nano-sized L12 precipitates in CoCrFeNiAlTi HEAs has been proposed in this work.Results demonstrate the pitting corrosion potential can be elevated from 258 mVSCE to 603 mVSCE by increasing the precipitate content to 38 wt.%.Such an improvement in localized corrosion resistance can be attributed to two aspects.Firstly,L12 precipitates tend to be dissolved during the corrosion process,which promotes the heterogeneous nucleation of protective Cr2 O3 due to the rapid deposition of oxides/hydroxides of Al/Ti,and improves the passive film stability due to the Crrich FCC matrix.Secondly,the dissolution kinetic inside the pits can be suppressed on account of the enrichment of Cr element in the FCC matrix,thus inhibiting the pitting growth.In summary,the current work not only reveals the mechanisms of the nano-sized L12 precipitates upon the corrosion behavior,but also provides a strategy for designing corrosion-resistant HEA.
基金financial support from the National Natural Science Foundation of China (No.51201162)the Youth Innovation Foundation from Institute of Metal Research, Chinese Academy of Sciences
文摘A heat treatment process, quenching-tempering-partitioning (Q-T-P), has been applied to a low carbon martensitic stainless steel 06Crl3Ni4Mo. By using this process, ultrafine reversed austenite can be obtained at room temperature. The microstructures of the reversed austenite and the martensite matrix were characterized by transmission electron microscopy (TEM) and energy dispersive spectroscopy (EDS) in detail. The results show that the ultrafine reversed austenite is enriched in Ni resulting in the austenite stability at room temperature. Two new types of nano-scale carbide precipitates are found in the martensite matrix. Detailed analysis suggests that the two nano-scale precipitates can be identified as ω phase and λ phase carbides, respectively. The orientation relationship between the ω phase and matrix is [011]α [/[2110]ω and (211)α//(0110)ω, while that between the X phase precipitate and matrix is [011]α][[0001]λ and (200)α/(1210)λ. For the present steel, the ultrafine reversed austenite and carbide precipitates obtained by Q-T-P treatment provide a good combination of high strength and toughness.
