中文
Earlier issues
Announcement
More
Progress in Chemistry 2009, Vol. 21 Issue (01): 143-151 Previous Articles   Next Articles

• Review •

Preparation, Microstructure Control and Magnetic Properties of 1D Ferromagnetic Metal Nanomaterials

Fan Xi'an;Guan Jianguo**;Wang Wei;Wang Yilong;Tong Guoxiu;Mou Fangzhi   

  1. (State Key Laboratory of Advanced Technology for Materials Synthesis and Processing, Wuhan University of Technology, Wuhan 430070, China)
  • Received: Revised: Online: Published:
  • Contact: Guan Jianguo E-mail:guanjg@whut.edu.cn
PDF ( 2498 ) Cited
Export

EndNote

Ris

BibTeX

One dimension (1D) ferromagnetic metal nanomaterials have not only distinctive effect of common nanomaterials, but also unique shape and magnetic anisotropy. As the important building blocks of the advanced electromagnetic functional materials, 1D ferromagnetic metal nanomaterials have important applications in some areas such as high-density magnetic memories, sensitive elements, electromagnetic wave absorbing materials, catalyst, medicine and biology etc. In this paper, the microstructure controlling methods about the morphology parameters (including diameter, length and aspect ratio) and crystal plane preferred orientation, and the effect of microstructure on magnetic properties are reviewed in detail in terms of the preparation technology of 1D ferromagnetic metal nanomaterials. As a consequence, the future research in 1D ferromagnetic metal nanomaterials should be focused on the innovative and resultful microstructure controlling methods, preferred orientation and assembly technology, the intrinsical relation between electromagnetic properties and microstructure, and the actual application in electricity and magnetism.

Contents
1 Introduction
2 Preparation of 1D ferromagnetic metal nanomaterials by template-based methods
2.1 Controlled-synthesis of 1D ferromagnetic nanostructure by template-based electrochemical deposition method
2.2 Controlled-synthesis of 1D ferromagnetic nanostructure by encapsulating in carbon nanotubes
3 Preparation of 1D ferromagnetic metal nanomaterials by template-free chemical methods
3.1 Controlled-synthesis of 1D ferromagnetic nanostructure by thermal-decomposition-based chemical vapor deposition methods
3.2 Controlled-synthesis of 1D ferromagnetic nanostructure by electrospinning 3.3 Controlled-synthesis of 1D ferromagnetic nanostructure by low-temperature solution-phase methods
4 Effect of microstructure on the magnetic properties of 1D ferromagnetic metal nanomaterials
5 Conclusion

Key words: 1D nanomaterials, ferromagnetic metal materials, microstructure control, assembly, magnetic properties

CLC Number: 

[ 1 ]  Zeng H , Skomski R , Menon L , et al . Phys. Rev. B , 2002 , 65 :art . no. 134426
[ 2 ]  Zhan YJ , Zheng C L , Liu Y K, et al . Mater. Lett . , 2003 , 57 :3265 —3268
[ 3 ]  Sellmyer D J , Zheng M, Skomski R. J . Phys. : Condens. Matter. ,2001 , 13 : R433 —R460
[ 4 ]  Whitney TM, Jiang J S , Searson P C , et al . Science , 1993 , 261 :1316 —1319
[ 5 ]  Bao J C , Tie C Y, Xu Z, et al . Adv. Mater. , 2001 , 13 : 1631 —1633
[ 6 ]  Wang YW, Zhang L D , Meng G W, et al . J . Phys. Chem. B ,2002 , 106 : 2502 —2507
[ 7 ]  Rudkowski P , Rudkowska G, Zaluska A. IEEE Trans. Magn. ,1992 , 28 : 1899 —1903
[ 8 ]  Wu M Z, Zhao Z S , He H H , et al . J . Magn. Magn. Mater. ,2000 , 217 : 89 —92
[ 9 ]  Wu M Z, He H H , Zhao Z S , et al . J . Phys. D: Appl . Phys. ,2000 , 33 : 2398 —2401
[10 ]  Cao H Q , Wang L D , Qiu Y, et al . ChemPhysChem , 2006 , 7 :1500 —1504
[11 ]  Peng Y, Shen T H , Ashworth B , et al . Appl . Phys. Lett . , 2003 ,83 : 362 —364
[12 ]  Gong C R , Chen D R , Jiao X L , et al . J . Mater. Chem. , 2002 ,12 : 1844 —1847
[13 ]  Yang S G, Zhu H , Yu D L , et al . J . Magn. Magn. Mater. , 2000 ,222 : 97 —100
[14 ]  Yang Y, Zhang B S , Xu W D , et al . J . Alloys Compd. , 2004 ,365 : 300 —302
[15 ]  Kida A , Kajiyama H , Heike S. Appl . Phys. Lett . , 1999 , 75 :540 —542
[16 ]  Sugawara A , Coyle T, Hembree G G, et al . Appl . Phys. Lett . ,1997 , 70 : 1043 —1045
[17 ]  Mohaddes-Ardabili L , Zheng H , Ogale S B , et al , Nature Mater. ,2004 , 3 : 533 —538
[18 ]  Chen J Y, Wiley B J , Xia YN. Langmuir , 2007 , 23 : 4120 —4129
[19 ]  Hu H N , Chen H Y, Chen J L , et al . Physica B : Condensed Matter , 2005 , 368 : 100 —104.
[20 ]  Satishkumar B C , Govindaraj A , Vanitha P V , et al . Chem. Phys.Lett . , 2002 , 362 : 301 —306
[21 ]  Grobert N , Hsu W K, Zhu YQ , et al . Appl . Phys. Lett . , 1999 ,75 : 3363 —3365
[22 ]  Shpak A P , Kolesnik S P , Mogilny GS , et al . Acta Mater. , 2007 ,55 : 1769 —1778
[23 ]  Han WQ , Kohler-Redlich P , Scheu C. Adv. Mater. , 2000 , 12 :1356 —1359
[24 ]  Leonhardt A , Ritschel M, Elefant D , et al . J . Appl . Phys. , 2005 ,98 : art . no. 074315
[25 ]  Zhan S H , Chen D R , Jiao X L , et al . J . Colloid Interface Sci . ,2007 , 308 : 265 —270
[26 ]  Zhu Y, Zhang J C , Zhai J , et al . Thin Solid Films , 2006 , 510 :271 —274
[27 ]  Li D , Herricks T, Xia Y N. Appl . Phys. Lett . , 2003 , 83 : 4586 —4588
[28 ]  Wu H , Zhang R , Liu X X, et al . Chem. Mater. , 2007 , 19 :3506 —3511
[29 ]  Yang J B , Xu H , You S X, et al . J . Appl . Phys. , 2006 , 99 : art .no. 08Q507
[30 ]  Huelser T P , Wiggers H , Ifeacho P , et al . Nanotechnology , 2006 ,17 : 3111 —3115
[31 ]  Lee G H , Huh S H , Jeong J W, et al . Scripta Mater. , 2003 , 49 :1151 —1155
[32 ]  Li X C , Gong R Z, Nie Y, et al . Mater. Chem. Phys. , 2005 , 94 :408 —411
[33 ]  Nie Y, He H H , Zhao Z S , et al . J . Magn. Magn. Mater. , 2006 ,306 : 125 —129
[34 ]  Ai Z H , Lu L R , Li J P , et al . J . Phys. Chem. C , 2007 , 111 :4087 —4093
[35 ]  Wang J , Peng Z M, Huang YJ , et al . J . Crystal Growth , 2004 ,263 : 616 —619
[36 ]  Zhang Z T, Blom D A , Gai Z, et al . J . Am. Chem. Soc. , 2003 ,125 : 7528 —7529
[37 ]  Lian S Y, Wang E B , Gao L , et al . Solid State Commun. , 2004 ,132 : 375 —378
[38 ]  聂彦(Nie Y) , 赵振声(Zhao Z S) , 何华辉(He H H) . 信息记录材料( Inform. Record. Mater. ) , 2005 , 6 (4) : 49 —52
[39 ]  Wei D C , Liu YQ , Cao L C , et al . J . Am. Chem. Soc. , 2007 ,129 : 7364 —7368
[40 ]  Knipping J , Wiggers H , Kock B F , et al . Nanotechnology , 2004 ,151 : 1665 —1670
[41 ]  龚荣洲(Gong R Z) , 李享成(Li X C) . 功能材料(J . Funct .Mater. ) , 2005 , 36 (11) : 1096 —1700
[42 ]  Napolsky K S , Eliseev A A , Knotko A V , et al . Mater. Sci . Eng.C , 2003 , 23 : 151 —154
[43 ]  Eliseev A A , Napolskii K S , Lukashin A V. J . Magn. Magn.Mater. , 2004 , 272P276 : 1609 —1610
[44 ]  Li D , Wang Y L , Xia Y N. Nano Lett . , 2003 , 3 : 1167 —1171.
[45 ]  Theron A , Zussmanand E , Yarin A L. Nanotechnology , 2001 , 12 :384 —390
[46 ]  Sigmund W, Yuh J H , Park H , et al . J . Am. Ceram. Soc. , 2006 ,89 : 395 —407
[47 ]  Loscertales I G, Barrero A , Guerrero I , et al . Science , 2002 , 295 :1695 —1698
[48 ]  Li D , Xia Y N. Adv. Mater. , 2004 , 16 : 1151 —1170
[49 ]  Loscertales I G, Barrero A , Márquez M, et al . J . Am. Chem.Soc. , 2004 , 126 : 5376 —5377
[50 ]  Bognitzki M, Czado W, Frese T, et al . Adv. Mater. , 2001 , 13 :70 —72
[51 ]  Li D , Wang Y, Xia Y. Adv. Mater. , 2004 , 16 : 361 —366
[52 ]  赵涛(Zhao T) , 孙蓉(Sun R) , 冷静(Leng J ) 等. 化学进展(Prog. Chem. ) , 2007 , 19 : 1704 —1709
[53 ]  Wang J , Chen Q W, Zeng C , et al . Adv. Mater. , 2004 , 16 :137 —140
[54 ]  王成伟(Wang CW) , 彭勇(Peng Y) , 潘善林(Pan SL) 等. 物理学报(Acta Phys. Sinica) , 1999 , 48 (11) : 2146 —2150
[55 ]  赵振声(Zhao Z S) , 吴明忠(Wu M Z) , 何华辉(He H H) . 华中理工大学学报(J . Huazhong Univ. Sci . Tech. ) , 1998 , 26 (7) : 74 —76
[56 ]  Zheng M, Menon L , Zeng H , et al . Phys. Rev. B , 2000 , 62 :12282 —12286
[57 ]  Zeng H , Zheng M, Skomski R , et al . J . Appl . Phys. , 2000 , 87 :4718 —4720
[58 ]  Wang J B , Zhou X Z, Liu Q F , et al . Nanotechnology , 2004 , 15 :485 —489
[1] Liangchun Li, Renlin Zheng, Yi Huang, Rongqin Sun. Self-Sorting Assembly in Multicomponent Self-Assembled Low Molecular Weight Hydrogels [J]. Progress in Chemistry, 2023, 35(2): 274-286.
[2] Keqing Wang, Huimin Xue, Chenchen Qin, Wei Cui. Controllable Assembly of Diphenylalanine Dipeptide Micro/Nano Structure Assemblies and Their Applications [J]. Progress in Chemistry, 2022, 34(9): 1882-1895.
[3] Meng Wang, He Song, Yewen Li. Three Dimensional Self-Assembled Blue Phase Liquid Crystalline Photonic Crystal [J]. Progress in Chemistry, 2022, 34(8): 1734-1747.
[4] Bao Li, Lixin Wu. Liquid Condensed Matter Mediated Assembly and Functionality of Dispersoid [J]. Progress in Chemistry, 2022, 34(7): 1600-1609.
[5] Dongxue Han, Xue Jin, Wangen Miao, Tifeng Jiao, Pengfei Duan. Responsiveness of Excited State Chirality Based on Supramolecular Assembly [J]. Progress in Chemistry, 2022, 34(6): 1252-1262.
[6] Hang Yin, Zhi Li, Xiaofeng Guo, Anchao Feng, Liqun Zhang, San Hoa Thang. Selection Principle of RAFT Chain Transfer Agents and Universal RAFT Chain Transfer Agents [J]. Progress in Chemistry, 2022, 34(6): 1298-1307.
[7] Jiahui Ma, Wei Yuan, Simin Liu, Zhiyong Zhao. Self-Assembly of Small Molecule Modified DNA and Their Application in Biomedicine [J]. Progress in Chemistry, 2022, 34(4): 837-845.
[8] Hong Li, Xiaodan Shi, Jieling Li. Self-Assembled Peptide Hydrogel for Biomedical Applications [J]. Progress in Chemistry, 2022, 34(3): 568-579.
[9] Yuling Liu, Tengda Hu, Yilian Li, Yang Lin, Borsali Redouane, Yingjie Liao. Fast Self-Assembly Methods of Block Copolymer Thin Films [J]. Progress in Chemistry, 2022, 34(3): 609-615.
[10] Chuxuan Yan, Qinglin Li, Zhengqi Gong, Yingzhi Chen, Luning Wang. Organic Semiconductor Nanostructured Photocatalysts [J]. Progress in Chemistry, 2021, 33(11): 1917-1934.
[11] Yena Feng, Shuhe Liu, Shubo Zhang, Tong Xue, Honglin Zhuang, Anchao Feng. Preparation of SiO2/Polymer Nanocomposites Based on Polymerization-Induced Self-Assembly [J]. Progress in Chemistry, 2021, 33(11): 1953-1963.
[12] Zixuan Wang, Yuefei Wang, Wei Qi, Rongxin Su, Zhimin He. Design, Self-Assembly and Application of DNA-Peptide Hybrid Molecules [J]. Progress in Chemistry, 2020, 32(6): 687-697.
[13] Kangkang Zhi, Xin Yang. Natural Product Gels and Their Gelators [J]. Progress in Chemistry, 2019, 31(9): 1314-1328.
[14] Dongmei Yao, Weiqi Zhang, Qian Xu, Li Xu, Huaming Li, Huaneng Su. Membrane Electrode Assembly for High Temperature Polymer Electrolyte Membrane Fuel Cell Based on Phosphoric Acid-Doped Polybenzimidazole [J]. Progress in Chemistry, 2019, 31(2/3): 455-463.
[15] Yuekun Ye, Bin Chi, Shijie Jiang, Shijun Liao. Enhancing the Durability of Membrane Electrode Assembly of Proton Exchange Membrane Fuel Cells [J]. Progress in Chemistry, 2019, 31(12): 1637-1652.