The oxidation behaviors of high-entropy alloys AlxCoCrFeNi(x=0.15, 0.4) in supercritical water at 550 and 600 °C were studied, and compared with HR3 C steel. All oxide films formed on alloys are composed of spine...The oxidation behaviors of high-entropy alloys AlxCoCrFeNi(x=0.15, 0.4) in supercritical water at 550 and 600 °C were studied, and compared with HR3 C steel. All oxide films formed on alloys are composed of spinel type(Fe, Cr)3O4 oxides. Compared with the oxide film on HR3 C steel, thinner oxide films with smaller size of oxide particles were realized on Al0.15 CoCrFeNi and Al0.4CoCrFeNi, indicating a superior oxidation resistance of Al0.15 CoCrFeNi and Al0.4CoCrFeNi to HR3 C steel. Electrochemical test results reveal that surface oxide films greatly affect the electrochemical corrosion behavior of the oxidized alloys in 3.5% Na Cl solution. The relatively high corrosion resistance of oxidized Al0.15 CoCrFeNi and HR3 C is attributed to the formation of thick and multi-layer oxides.展开更多
Refractory high entropy alloys have superior mechanical properties at high temperatures, and the oxidation behavior of these alloys is very important. The present work investigated the high temperature oxidation behav...Refractory high entropy alloys have superior mechanical properties at high temperatures, and the oxidation behavior of these alloys is very important. The present work investigated the high temperature oxidation behavior of three alloys with compositions of TiNbTa0.5Zr, TiNbTa0.5ZrAl and TiNbTa0.5ZrAlMo0.5, and the effects of alloying elements were discussed. Results indicated that the oxidation rates of the TiNbTa0.5Zr and TiNbTa0.5ZrAl alloys are controlled by diffusion, and obey the exponential rule. However, the oxidation rate of the TiNbTa0.5ZrAlMo0.5 alloy is controlled by interface reaction, and obeys the linear rule. The addition of Al leads to a better oxidation resistance by forming a protective oxide scale. However, the protection of Al-rich scale is weakened by the addition of Mo. Extensive pores and cracks occur in the oxide scale of the TiNbTa0.5ZrAlMo0.5 alloy, resulting in a significant decrease in oxidation resistance.展开更多
This work reviews recent progress in the alloy design,microstructure,and mechanical properties of refractory high-entropy alloys(RHEAs).What’s more,the underlying strengthening mechanisms and deformation behavior are...This work reviews recent progress in the alloy design,microstructure,and mechanical properties of refractory high-entropy alloys(RHEAs).What’s more,the underlying strengthening mechanisms and deformation behavior are discussed.Composed mainly of near-equimolar refractory elements,RHEAs have superior mechanical properties,especially at high temperatures.However,many of them have limited room-temperature ductility.Much work has been done to solve this trade-off,and some of the RHEAs have the potential to be used for high-temperature applications in the future.In addition to their mechanical properties,RHEAs have other attractive properties,such as biocompatibility and wear resistance,which are discussed.Finally,current problems and future suggestions for RHEAs are discussed.展开更多
Refractory high-entropy alloys(HEAs) exhibit remarkable mechanical properties desired for high-temperature applications. However, their oxidation resistance at high temperatures received less attention. Recent work in...Refractory high-entropy alloys(HEAs) exhibit remarkable mechanical properties desired for high-temperature applications. However, their oxidation resistance at high temperatures received less attention. Recent work indicates that MoTaTiCrAl alloy exhibits excellent oxidation resistance,but the effects of Al and Cr remain unclear. In this work, we demonstrate that the addition of Al is unnecessary for preventing oxidation of the MoTaTiCrAl alloy and the removal of Al leads to a more oxidation resistant MoTaTiCr medium entropy alloy. Structural and chemical analyses indicate that the excellent oxidation resistance of MoTaTiCr is mainly associated with the formation of continuous CrTaO4 oxide layer.The results indicate that complex oxides can be adopted as effective candidates for enhancement of oxidation resistance,in addition to typical strategy of forming Al2O3, Cr2O3 or SiO2 barrier layer.展开更多
基金Projects(51134013,51171037,51101024)supported by the National Natural Science Foundation of China
文摘The oxidation behaviors of high-entropy alloys AlxCoCrFeNi(x=0.15, 0.4) in supercritical water at 550 and 600 °C were studied, and compared with HR3 C steel. All oxide films formed on alloys are composed of spinel type(Fe, Cr)3O4 oxides. Compared with the oxide film on HR3 C steel, thinner oxide films with smaller size of oxide particles were realized on Al0.15 CoCrFeNi and Al0.4CoCrFeNi, indicating a superior oxidation resistance of Al0.15 CoCrFeNi and Al0.4CoCrFeNi to HR3 C steel. Electrochemical test results reveal that surface oxide films greatly affect the electrochemical corrosion behavior of the oxidized alloys in 3.5% Na Cl solution. The relatively high corrosion resistance of oxidized Al0.15 CoCrFeNi and HR3 C is attributed to the formation of thick and multi-layer oxides.
基金Project(51671217)supported by the National Natural Science Foundation of ChinaProject(CX2017B047)supported by the Program of Innovation for Postgraduate of Hunan Province,China
文摘Refractory high entropy alloys have superior mechanical properties at high temperatures, and the oxidation behavior of these alloys is very important. The present work investigated the high temperature oxidation behavior of three alloys with compositions of TiNbTa0.5Zr, TiNbTa0.5ZrAl and TiNbTa0.5ZrAlMo0.5, and the effects of alloying elements were discussed. Results indicated that the oxidation rates of the TiNbTa0.5Zr and TiNbTa0.5ZrAl alloys are controlled by diffusion, and obey the exponential rule. However, the oxidation rate of the TiNbTa0.5ZrAlMo0.5 alloy is controlled by interface reaction, and obeys the linear rule. The addition of Al leads to a better oxidation resistance by forming a protective oxide scale. However, the protection of Al-rich scale is weakened by the addition of Mo. Extensive pores and cracks occur in the oxide scale of the TiNbTa0.5ZrAlMo0.5 alloy, resulting in a significant decrease in oxidation resistance.
基金the National Natural Science Foundation of China(Nos.51871147,51821001)the Shanghai Aerospace Advanced Technology Joint Research Fund,China(No.USCAST2020-35).
文摘This work reviews recent progress in the alloy design,microstructure,and mechanical properties of refractory high-entropy alloys(RHEAs).What’s more,the underlying strengthening mechanisms and deformation behavior are discussed.Composed mainly of near-equimolar refractory elements,RHEAs have superior mechanical properties,especially at high temperatures.However,many of them have limited room-temperature ductility.Much work has been done to solve this trade-off,and some of the RHEAs have the potential to be used for high-temperature applications in the future.In addition to their mechanical properties,RHEAs have other attractive properties,such as biocompatibility and wear resistance,which are discussed.Finally,current problems and future suggestions for RHEAs are discussed.
基金supported by the National Key Research and Development Program of China (2018YFA0703600)the National Science Fund for Distinguished Young Scholars (51825104)+3 种基金the Key Research Program of Frontier Sciences of Chinese Academy of Sciences (QYZDY-SSW-JSC017)the Strategic Priority Research Program of Chinese Academy of Sciences (XDB30000000)the Key Basic and Applied Research Program of Guangdong Province, China (2019B030302010)the National Natural Science Foundation of China (11790291 and 61888102)。
文摘Refractory high-entropy alloys(HEAs) exhibit remarkable mechanical properties desired for high-temperature applications. However, their oxidation resistance at high temperatures received less attention. Recent work indicates that MoTaTiCrAl alloy exhibits excellent oxidation resistance,but the effects of Al and Cr remain unclear. In this work, we demonstrate that the addition of Al is unnecessary for preventing oxidation of the MoTaTiCrAl alloy and the removal of Al leads to a more oxidation resistant MoTaTiCr medium entropy alloy. Structural and chemical analyses indicate that the excellent oxidation resistance of MoTaTiCr is mainly associated with the formation of continuous CrTaO4 oxide layer.The results indicate that complex oxides can be adopted as effective candidates for enhancement of oxidation resistance,in addition to typical strategy of forming Al2O3, Cr2O3 or SiO2 barrier layer.