难熔金属
材料科学
延展性(地球科学)
冶金
蠕动
合金
高温合金
腐蚀
散裂
化石燃料
结构材料
燃烧
镍铬合金
涡轮机
可再生能源
灾难性故障
剥落
环境科学
涡轮叶片
压缩(物理)
索里达
高温腐蚀
能量转换
核工程
碳化物
复合材料
作者
Frauke Hinrichs,Georg Winkens,Lorenz Kramer,Gabriely Medeiros de Souza Falcão,Eric N. Hahn,Daniel Schliephake,Michael K. Eusterholz,Sandipan Sen,Mathias C. Galetz,Haruyuki Inui,Alexander Kauffmann,Martin Heilmaier
出处
期刊:Nature
[Nature Portfolio]
日期:2025-10-08
卷期号:646 (8084): 331-337
被引量:11
标识
DOI:10.1038/s41586-025-09516-8
摘要
Even with the rapid development of renewable energy sources, improving the efficiency of energy conversion from fossil or synthetic fuels remains a challenge because, for example, combustion engines in long-range aircraft will still be needed in the upcoming decades1. Increasing their operating temperatures (1,050-1,150 °C (refs. 2-4)) is one option. This requires replacing single-crystalline Ni-based superalloys in the hottest sections of turbines by refractory-element-based materials, which exhibit much higher solidus temperatures beyond 2,000 °C (refs. 5-7). Here we introduce a single-phase Cr-36.1Mo-3Si (at.%) alloy that meets, for the first time, to our knowledge, the most important critical requirements for refractory-element-based materials: (1) relevant resistance against pesting, nitridation and scale spallation at elevated temperatures, minimum up to 1,100 °C, and (2) sufficient compression ductility at room temperature. Although strength and creep resistance in such alloys were already superior to Ni-based superalloys in several cases, oxidation/corrosion resistance, mandatory to withstand the combustion atmosphere, and ductility/toughness, needed for damage tolerance and device setting, still pose barriers for the development or application of refractory-element-based candidate materials. Any previous successful attempts to address the otherwise catastrophic oxidation of Mo and nitridation of Cr during oxidation suffered from a loss in ductility at ambient temperatures.
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