Magnetic properties of sputtered anisotropic Pr–Fe–B thin films with different structures and antiferromagnetic materials 被引量：2

Magnetic properties of sputtered anisotropic Pr–Fe–B thin films with different structures and antiferromagnetic materials

原文传递

导出

摘要 Anisotropic Pr-Fe-B films with soft-magnetic layer （Fe） and/or antiferromagnetic layer （Mn, FeMn or MnO） were prepared by direct-current （DC） magnetron sputtering on Si （100） substrates heated at 650℃. The influence of four types＇ different structures on the magnetic properties of Pr-Fe-B films was investigated. The phase and magnetic properties were characterized by means of X-ray diffraction （XRD） and superconducting quantum interference device （SQUID）. Addition of anti-ferromagnetic layer enhances both the coercivity and the remanence ratios of Pr-Fe-B films with suitable structures. The interface number increases and the antiferromagnetic-ferromagnetic exchange interaction is likely to become stronger, which affect the improvement of magnetic properties. To further understand the influence of structures with soft-magnetic Fe layer and/or antifer- romagnetic FeMn layer on the magnetic properties of Pr-Fe-B hard-magnetic films, the thickness of Pr-Fe-B layer was designed to decrease from 600 to 50 nm. The improvement of magnetic properties becomes obvious in Mo（50 nm）/Pr-Fe-B（25 nm）Mo（2 nm）FeMn（20 nm）Mo （2 nm）Pr-Fe-B（25 nm）/Mo（50 rim） film. Anisotropic Pr-Fe-B films with soft-magnetic layer （Fe） and/or antiferromagnetic layer （Mn, FeMn or MnO） were prepared by direct-current （DC） magnetron sputtering on Si （100） substrates heated at 650℃. The influence of four types＇ different structures on the magnetic properties of Pr-Fe-B films was investigated. The phase and magnetic properties were characterized by means of X-ray diffraction （XRD） and superconducting quantum interference device （SQUID）. Addition of anti-ferromagnetic layer enhances both the coercivity and the remanence ratios of Pr-Fe-B films with suitable structures. The interface number increases and the antiferromagnetic-ferromagnetic exchange interaction is likely to become stronger, which affect the improvement of magnetic properties. To further understand the influence of structures with soft-magnetic Fe layer and/or antifer- romagnetic FeMn layer on the magnetic properties of Pr-Fe-B hard-magnetic films, the thickness of Pr-Fe-B layer was designed to decrease from 600 to 50 nm. The improvement of magnetic properties becomes obvious in Mo（50 nm）/Pr-Fe-B（25 nm）Mo（2 nm）FeMn（20 nm）Mo （2 nm）Pr-Fe-B（25 nm）/Mo（50 rim） film.

作者 Fang Yang Wei Liu Zhi-Dong Zhang

机构地区 Shenyang National Laboratory for Materials Science Superconducting Materials Research Center

出处《Rare Metals》 SCIE EI CAS CSCD 2016年第12期926-929,共4页 稀有金属（英文版）

基金 financially supported by the National Key Basic Research Program of China (No. 2010CB934603) the National Nature Science Foundation of China (Nos. 50931006 and 50971123)

关键词 Magnetic materials Thin films COERCIVITY Hysteresis loop SPUTTERING Magnetic materials Thin films Coercivity Hysteresis loop Sputtering

分类号 TB383.2 [一般工业技术—材料科学与工程]

引文网络
相关文献

参考文献2

1Ce Yang,Yang-Long Hou.Advance in the chemical synthesis and magnetic properties of nanostructured rare-earth-based permanent magnets[J].Rare Metals,2013,32(2):105-112. 被引量：14
2Cheng-Bao Jiang,Shi-Zhong An.Recent progress in high temperature permanent magnetic materials[J].Rare Metals,2013,32(5):431-440. 被引量：23

二级参考文献55

1Tang, Cuiyong, Xiao, Zhiyu, Luo, Fei, Wang, Jun, Ma, Chunyu, Zhang, Wen.Structural characteristics and magnetic properties of bulk nanocrystalline Fe_(84)Zr_2Nb_4B_(10) alloy prepared by mechanical alloying and spark plasma sintering consolidation[J].Rare Metals,2012,31(3):255-259. 被引量：5
2Liu Jinjun,Wang Rong,Yin Hongyun,Liu Xincai,Si Pingzhan,Du Juan.Structure and magnetostriction of Tb_(0.4)Nd_(0.6)(Fe_(0.8)Co_(0.2))_(1.90) alloy prepared by solid-state synthesis[J].Rare Metals,2012,31(6):547-551. 被引量：2
3Li, Zhi, Ding, Hao, Zhang, Jun, Wang, Hanbin, Wang, Hao.Effects of annealing temperature and time on microstructure and magnetic properties of Pr-Co thin films[J].Rare Metals,2012,31(2):121-124. 被引量：4
4Jones N. The pull of stronger magnets. Nature. 2011;472:22.
5Gutfleisch O, Willard MA, Bruck E, Chen CH, Sankar SG, Liu JP. Magnetic materials and devices for the 21st century: stronger, lighter, and more energy efficient. Adv Mater. 2011;23(7):821.
6Coey JMD. Hard magnetic materials: a perspective. IEEE Trans Magn. 2011 ;47(21):4671.
7Fingers RT, Rubertus CS. Application of high temperature magnetic materials. 1EEE Trans Magn. 2000;36(5):3373.
8Gutfleisch O, M~iller KH, Khlopkov K, Wolf M, Yan A, Sch~ifer R, Gemming T, Schultz L. Evolution of magnetic domain structures and coercivity in high-performance SmCo 2:17-type permanent magnets. Acta Mater. 2006;54(4):997.
9Provenza A J, Montague GT, Jansen M J, Palazzolo AB, Jansen RH. High temperature characterization of a radial magnetic bearing for turbomachinery. J Eng Gas Turbines Power. 2005;127(2):437.
10Liu JF, Ding Y, Hadjipanayis GC. Effect of iron on the high temperature magnetic properties and microstructure of Sm(Co, Fe, Cu, Zr)~ permanent magnets. J Appl Phys. 1999;85(3): 1670.

共引文献32

1Tian-Li Zhang,Bo Zhang,Hui Wang,Cheng-Bao Jiang,Zhi-Hong Zhang,Xiao-Qing Wang,Wei Zhang.Low remanence temperature coefficient Sm1-xErx(Co,Fe,Cu,Zr)z magnets operating up to 400℃[J].Rare Metals,2020,39(1):70-75. 被引量：3
2Jian-Hua Zuo,Ming Yue,Qing-Mei Lu,Dong-Tao Zhang,Xue-Xu Gao,Jiu-Xing Zhang,Zhao-Hui Guo,Wei Li.Structure, magnetic properties, and thermal stability of Sm(1-x)Tm_xCo_5compounds[J].Rare Metals,2014,33(2):176-179.
3Yu-Chao Liu,Hong-Wei Li,Kuo-She Li,Dun-Bo Yu,Jin-Ling Jin,Yang Luo,Liang Sun,Ning-Tao Quan.Magnetic properties optimization of nanocomposite Nd_9Fe_(85)B_6 magnets by controlling microstructure of as-quenched ribbons[J].Rare Metals,2014,33(3):299-303. 被引量：3
4Ren-Quan Wang,Biao Chen,Jun Li,Ying Liu,Qing Zheng.Structural and magnetic properties of backward extruded Nd–Fe–B ring magnets made by different punch chamfer radius[J].Rare Metals,2014,33(3):304-308. 被引量：4
5安士忠,张天丽,蒋成保.高性能抗氧化SmCo高温永磁材料[J].航空学报,2014,35(10):2794-2801. 被引量：6
6吕海燕,李双明,钟宏,傅恒志.定向凝固NdFeB永磁合金中包晶相的取向生长研究[J].稀有金属,2015,39(2):111-118. 被引量：8
7Yun-Ping Yu,Ying Liu,Jun Li,Qing Zheng,Ren-Quan Wang.Desorption–recombination behavior of as-disproportionated NdFeCoB compacts by reactive deformation[J].Rare Metals,2015,34(2):89-94. 被引量：2
8Hu Liu,Shen-Gen Zhang,De-An Pan,Yi-Fan Liu,Bo Liu,Jian-Jun Tian,Alex A.Volinsky.Mechanism of CeMgAl_(11)O_(19):Tb^(3+) alkaline fusion with sodium hydroxide[J].Rare Metals,2015,34(3):189-194. 被引量：2
9Hai-Cheng Wang,Zhi-Ran Yan,Ling Deng,Hua Dong,Yi-He Jia,Ning Ma,Jun He,Guang-Hua Yu.Synthesis and surface modification of cobalt nanoparticles and electromagnetic property of Co/PPy nanocomposites[J].Rare Metals,2015,34(4):223-228. 被引量：2
10余云萍,李军,刘颖,王仁全,郑青,连利仙.Highly oriented NdFeB nanocrystalline magnets from partially recombined compacts with ultrafine grain size by reactive deformation under low pressure[J].Journal of Rare Earths,2015,33(12):1298-1302. 被引量：6

同被引文献15

1Zi-Yi Zhu,Li Meng,Leng Chen.Strain-induced martensitic transformation in biomedical Co-Cr-W-Ni alloys[J].Rare Metals,2020,39(3):241-249. 被引量：7
2杜朝锋,黄英,秦秀兰.纳米磁性薄膜的研究进展[J].兵器材料科学与工程,2007,30(2):75-81. 被引量：4
3刘娜,王海,朱涛.COFeB/Pt多层膜的垂直磁各向异性研究[J].物理学报,2012,61(16):443-446. 被引量：6
4俱海浪,李宝河,吴志芳,张璠,刘帅,于广华.Co/Ni多层膜垂直磁各向异性的研究[J].物理学报,2015,64(9):489-493. 被引量：3
5Shuai Liu,Guang-Hua Yu,Mei-Yin Yang,Hai-Lang Ju,Bao-He Li,Xiao-Bai Chen.Co/Pt multilayer-based pseudo spin valves with perpendicular magnetic anisotropy[J].Rare Metals,2014,33(6):646-651. 被引量：7
6Yi Cao,Ming-Hua Li,Kang Yang,Xi Chen,Guang Yang,Qian-Qian Liu,Guang-Hua Yu.Enhancement of post-annealing stability in Co/Ni multilayers with perpendicular magnetic anisotropy by Au insertion layers[J].Rare Metals,2016,35(10):779-783. 被引量：2
7Guang-Hua Yu,Wen-Ling Peng,Jing-Yan Zhang.Progress in oxygen behaviors in two-dimensional thin films[J].Rare Metals,2017,36(3):155-167. 被引量：2
8苗君,姜勇.电场调控稀有金属化合物的磁性及自旋输运行为[J].稀有金属,2017,41(5):487-504. 被引量：3
9卢学鹏,俱海浪,刘帅,息剑峰,李宝河.CoSiB/Pd多层膜垂直各向异性及热稳定性的研究[J].稀有金属,2018,42(10):1054-1059. 被引量：4
10高伟波,王顺杰,孙梦翔,张俊良.钕铁硼磁钢居里温度的测定[J].中国稀土学报,2020,38(4):460-466. 被引量：6

引证文献2

1Ling-Ran Yu,Xiu-Lan Xu,Yun-Long Jia,Xuan Geng,Xu-Jie Ma,Yi-Fei Ma,Yong-Hui Zan,Chun Feng,Jiao Teng.Improved magnetic anisotropy of Co-based multilayer film with nitrogen dopant[J].Rare Metals,2021,40(10):2855-2861. 被引量：1
2吴梓坚,谢昊,王子生,雷国莉,吴琼.磁性材料居里温度测量结果影响因素分析[J].稀有金属,2025,49(1):146-152.

二级引证文献1

1沈如翠,安邦,王亚强,张金钰,刘刚,孙军.纳米金属多层膜微观结构及其力学性能研究进展[J].稀有金属,2023,47(4):555-569. 被引量：4

1韩欣欣.买吸尘器要“六看”[J].财会月刊,2008(8):93-93.
2陈红,陈楠,张培松,梁磊,洪源泽,杜菲,王春忠.锂离子电池正极材料LiFe(MoO4)2的制备及其电化学性质[J].吉林大学学报（理学版）,2015,53(6):1312-1315. 被引量：1
3韩欣欣.买吸尘器要六看[J].家庭科技,2008(4):15-15.
4谢中.反铁磁材料微观磁结构研究手段的新进展[J].物理,2001,30(6):384-385.
5刘新元,谢飞翔,张升原,戴远东,马平,王守证,刘乐园,聂瑞娟.超导量子干涉仪计算机自动控制系统[J].低温与超导,2001,29(2):41-44.
6刘亚南,刘强春,戴建明.水热合成法制备Fe3O4纳米片及表征[J].纳米科技,2010,7(1):64-68.
7Robert L.Fagaly.超导传感器[J].传感器世界,1998,4(4):15-21.
8温伟祥,胡社军,黄拿灿.巨磁电阻效应薄膜研究进展及其应用[J].重庆师范学院学报（自然科学版）,2000,17(4):14-19. 被引量：8
9Sanusi Abdullahi,Musa Momoh,Kasim Uthman Isah.Electrical and Structural Properties of Radio Frequency （RF） Sputtered ZnO Thin Film at Low Substrate Temperature[J].Journal of Electrical Engineering,2014,2(1):12-19.
10FENG XuYong,SHEN Chen,FANG Xin,CHEN ChunHua.Nonstoichiometric Li_(1±x)Ni_(0.5)Mn_(1.5)O_4 with different structures and electrochemical properties[J].Chinese Science Bulletin,2012,57(32):4176-4180.

Rare Metals

2016年第12期

浏览历史

内容加载中请稍等...