Understanding atomic-scale phase separation of liquid Fe-Cu alloy 被引量：8

Understanding atomic-scale phase separation of liquid Fe-Cu alloy

导出

摘要 Using liquid Fe 60 Cu 40 alloy as a model, the structure of liquid Fe-Cu alloy systems is investigated in the temperature range 1200 2200 K, covering a large metastable undercooled regime, to understand the phase separation of liquid Fe-Cu alloys on the atomic scale. The total pair distribution functions (PDFs) indicate that liquid Fe 60 Cu 40 alloy is ordered in the short range and disordered in the long range. If the atom types are ignored, the total atom number densities and PDFs demonstrate that the atoms are distributed homogenously in the liquid alloy. However, the segregation of Fe and Cu atoms is very obvious with decreasing temperature. The partial PDFs and coordination numbers show that the Cu and Fe atoms are not apt to get together on the atomic scale at low temperatures; this will lead to large fluctuations and phase separation in liquid Fe-Cu alloy. Using liquid Fe6oCu4o alloy as a model, the structure of liquid Fe-Cu alloy systems is investigated in the temperature range 1200-2200 K, covering a large metastable undercooled regime, to understand the phase separation of liquid Fe-Cu alloys on the atomic scale. The total pair distribution functions （PDFs） indicate that liquid Fe60Cu40 alloy is ordered in the short range and dis- ordered in the long range. If the atom types are ignored, the total atom number densities and PDFs demonstrate that the atoms are distributed homogenously in the liquid alloy. However, the segregation of Fe and Cu atoms is very obvious with decreasing tem- perature. The partial PDFs and coordination numbers show that the Cu and Fe atoms are not apt to get together on the atomic scale at low temperatures; this will lead to large fluctuations and phase separation in liquid Fe-Cu alloy.

作者 WANG HaiPeng WEI BingBo

机构地区 Department of Applied Physics

出处《Chinese Science Bulletin》 SCIE EI CAS 2011年第32期3416-3419,共4页

基金 supported by the National Natural Science Foundation of China (50971103 and 50971105) the Program for New Century Excellent Talents, Natural Science Foundation of Shaanxi Province (2010JQ6004) Shaanxi Project for Young New Star in Science and Technology NPU Foundation for Fundamental Research

关键词 Fe-Cu合金液态合金原子尺度相分离 PDF格式数字显示对分布函数合金系统 liquid alloy phase separation atomic scale Fe-Cu alloy undercooling

分类号 O562 [理学—原子与分子物理]

引文网络
相关文献

参考文献21

1Boamfa M I, Kim M W, Maan J C, et al. Nature, 2003, 421:149-152.
2Greaves G N, Wilding M C, Fearn S, et al. Science, 2008, 322: 566-570.
3Cao X A, Yang Y. Appl Phys Lett, 2010, 96:151109.
4Kim C, Kang D M, Lee T Y, et al. Appl Phys Lett, 2009, 94:193504.
5Braicovich L, van den Brink J, Bisogni V, et al. Phys Rev Lett, 2010, 104:077002.
6Hong Z Y, Lu Y J, Xie W J, et al. Chinese Sci Bull, 2007, 52: 1446-1450.
7Reith D, Podloucky R. Phys Rev B, 2009, 80:054108.
8Kolli R P, Seidman D N. Acta Mater, 2008, 56:2073-2088.
9Park B J, Chen Y M, Ohkubo T. Intermetallics, 2009, 17:958-961.
10Yuge K, Seko A, Tanaka I, et al. Phys Rev B, 2005, 72:174201.

同被引文献39

1WANG Shouren,SONG Linghui,KANG Sukbong,CHO Jaehyung,WANG Yingzi.Deformation Behavior and Microstructure Evolution of Wrought Magnesium Alloys[J].Chinese Journal of Mechanical Engineering,2013,26(3):437-447. 被引量：10
2崔红保,郭景杰,毕维生,苏彦庆,吴士平,傅恒志.高温度梯度下Al-In偏晶合金定向凝固组织的演化规律[J].金属学报,2004,40(12):1253-1256. 被引量：8
3刘源,郭景杰,贾均,李言祥.Simulation of nucleation and coalescence of second phase droplets during earth-based solidification process of immiscible alloys[J].中国有色金属学会会刊：英文版,2005,15(3):479-484. 被引量：2
4Jie HE and Jiuzhou ZHAOInstitute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China.Microstructure Evolution in a Rapidly Solidified Cu85Fe15 Alloy Undercooled into the Metastable Miscibility Gap[J].Journal of Materials Science & Technology,2005,21(5):759-762. 被引量：3
5何杰,赵九洲,王晓峰,李中原.Al-Bi难混溶合金快速连续凝固的实验研究[J].金属学报,2006,42(1):67-72. 被引量：15
6杨全文,张涛.Molecular Dynamics Study of Icosahedral Clusters in Ni-Zr Amorphous Alloys[J].Chinese Physics Letters,2006,23(4):915-918. 被引量：2
7崔红保,郭景杰,苏彦庆,吴士平,李新中,傅恒志.Cu-Pb过偏晶合金颗粒生长和Ostwald熟化的相场法模拟[J].金属学报,2007,43(9):907-912. 被引量：12
8翟秋亚,杨扬,徐锦锋,郭学锋.快速凝固Cu-Sn亚包晶合金的电阻率及力学性能[J].物理学报,2007,56(10):6118-6123. 被引量：10
9周生贤.电子废物污染环境防治管理办法[J].再生资源研究,2007(6):1-4. 被引量：3
10王同敏,宋涛,许菁菁,蔡少武,李军,曹志强,李廷举.冷却斜槽法制备均质Al-Bi系难混溶合金[J].特种铸造及有色合金,2008,28(8):578-580. 被引量：1

引证文献8

1何杰,杨强龙,冯浩轩,江鸿翔,张丽丽,赵九洲.相分离非晶合金研究进展与展望[J].特种铸造及有色合金,2022,42(12):1453-1463.
2WANG Hai Peng,YANG ShangJing,WEI BingBo.Predicting macroscopic thermal expansion of metastable liquid metals with only one thousand atoms[J].Science China(Physics,Mechanics & Astronomy),2014,57(12):2235-2241. 被引量：1
3高卡,郭晓琴,张锐.Co-Cu-Pb三元合金的快速凝固组织及电学性能研究[J].机械工程学报,2017,53(18):99-105. 被引量：2
4陈斌,何杰,孙小钧,赵九洲,江鸿翔,张丽丽,郝红日.Fe-Cu-Pb合金液-液相分离及废旧电路板混合金属分级分离与回收[J].金属学报,2019,55(6):751-761. 被引量：9
5王佳康,接金川,李廷举.不同凝固条件下Cu80Fe20合金凝固组织以及磁性能研究[J].中国铸造装备与技术,2020,55(1):19-24. 被引量：1
6江鸿翔,黎旺,张丽丽,何杰,赵九洲.空间微重力条件下偏晶合金凝固研究进展[J].中国科学：物理学、力学、天文学,2020,50(4):83-90. 被引量：3
7王海鹏,王庆.表征液态金属结构双体分布函数的讲授方法[J].物理与工程,2022,32(1):155-161. 被引量：2
8徐山森,常健,翟斌,燕鹏旭,林茂杰,魏炳波.多元Ti-Cu基合金非晶形成过程的分子动力学模拟与落管实验研究[J].中国科学：技术科学,2024,54(3):477-489.

二级引证文献18

1王海鹏,常健.液态金属结构与性质教学中的课程思政[J].物理与工程,2022,32(6):183-188.
2TAN SiCong,ZHOU YiXin,WANG Lei,LIU Jing.Electrically driven chip cooling device using hybrid coolants of liquid metal and aqueous solution[J].Science China(Technological Sciences),2016,59(2):301-308. 被引量：8
3PAN Mingxiang,WANG Weihua,FAN Shuqian,ZHANG Qi,PAN Xiuhong,DENG Weijie,HU Liang,WEI Bingbo,WANG Haipeng,YIN Zhigang,FANG Jinghong,YU Jianding,ZHANG Xingwang,YUAN Zhangfu,JIANG Hongxiang,ZHAO Jiuzhou,WANG Gong.Space Materials Science in China:Ⅱ.Ground-based Researches and Academic Activities[J].空间科学学报,2020,40(5):950-955.
4ZHU MingWei,MA HaoBo,HE Jie,CHEN Bin,ZHANG LiLi,JIANG HongXiang,SUN XiaoJun,ZHAO JiuZhou.Metal recycling from waste memory modules efficiently and environmentally friendly by low-temperature alkali melts[J].Science China(Technological Sciences),2020,63(11):2275-2282. 被引量：2
5马浩博,朱明伟,何杰,陈斌,张丽丽,江鸿翔,孙小钧,赵九洲.废旧电路板的低温熔融混碱处理和有价金属提取[J].中国有色金属学报,2021,31(2):443-452. 被引量：7
6廖钰敏,姜明珠,胡蓉.电磁搅拌对C19400-SiC复合材料成分控制及性能的影响[J].材料研究与应用,2021,15(3):220-224.
7杨永辉,张林,张道琦,郭晓,王恩刚.Ti对Al-Bi-Sn难混溶合金凝固组织的影响[J].特种铸造及有色合金,2021,41(11):1410-1415. 被引量：4
8郭占成,高金涛,王哲,郭磊,王明涌.超重力冶金:科学原理、实验方法、技术基础、应用设计[J].工程科学学报,2021,43(12):1592-1617. 被引量：8
9王宝剑,翟薇,吴文华,魏炳波.原位自生TiB_(2)颗粒作用下偏晶Al_(62.5)Sn_(28.7)Cu_(8.8)合金的液相分离规律研究[J].中国科学：技术科学,2022,52(11):1679-1691.
10余彬,王恩志,李江平,赵立恒,徐洪傲.热解条件对废旧电路板微波热解特性影响[J].江西冶金,2023,43(2):114-120.

1贺战文,杜康.Fe-Cu合金机械合金化后的形貌及固溶研究[J].科技视界,2013(27):115-116.
2WANG Hai Peng,YANG ShangJing,WEI BingBo.Predicting macroscopic thermal expansion of metastable liquid metals with only one thousand atoms[J].Science China(Physics,Mechanics & Astronomy),2014,57(12):2235-2241. 被引量：1
3罗光,周上祺,胡先权.Cu-Ni和Fe-Cu合金中Cu含量与康普顿散射光子数的关系[J].核电子学与探测技术,2010,30(2):278-281. 被引量：2
4范宏义.电镀Fe—Cu合金[J].材料保护,2002,35(12):69-70.
5Zhitao HUANG,Wenhuai TIAN,Wenxiu LENG.Strengthening mechanism of Fe-Cu alloy during aging[J].Acta Metallurgica Sinica(English Letters),2012,25(5):401-408.
6成国栋,曹兴忠,吴建平,伍海彪,杨静,姜小盼,于润升,王宝义.应用正电子湮没谱学技术研究Fe-Cu合金微观缺陷的进展[J].材料导报,2013,27(3):133-137. 被引量：3
7LIU ZhiYong QIAO Hong.Investigation on the skewness for independent component analysis[J].Science China(Information Sciences),2011,54(4):849-860.
8李燕飞,桂太龙,徐小龙.无序CuZr和CuY合金的电阻和磁电阻(英文)[J].低温物理学报,2005,27(4):289-297.
9QIN Tao,WANG HaiPeng,WEI BingBo.Simulated evolution process of core-shell microstructures[J].Science China(Physics,Mechanics & Astronomy),2007,50(4):546-552. 被引量：1
10FAN Qi-wen,DU Ying-hui,ZHANG Rong.Preparation of 24Mg-Fe-Cu Target[J].Annual Report of China Institute of Atomic Energy,2012(1):98-98.

Chinese Science Bulletin

2011年第32期

浏览历史

内容加载中请稍等...

Understanding atomic-scale phase separation of liquid Fe-Cu alloy 被引量：8

参考文献21

同被引文献39

引证文献8

二级引证文献18

相关作者

相关机构

相关主题

浏览历史