Enhanced spin-valve effect in magnetically doped carbon nanotubes

被引:18
|
作者
Kirwan, D. F. [1 ]
de Menezes, V. M. [1 ,3 ]
Rocha, C. G. [1 ]
Costa, A. T. [2 ]
Muniz, R. B. [2 ]
Fagan, S. B. [4 ]
Ferreira, M. S. [1 ]
机构
[1] Trinity Coll Dublin, Sch Phys, Dublin 2, Ireland
[2] Univ Fed Fluminense, Inst Fis, BR-24020 Niteroi, RJ, Brazil
[3] Univ Fed Santa Maria, Dept Fis, BR-97105900 Santa Maria, RS, Brazil
[4] UNIFRA, Ctr Univ Franciscano, Area Ciencias Tecnol, BR-97010032 Santa Maria, RS, Brazil
来源
CARBON | 2009年 / 47卷 / 10期
基金
爱尔兰科学基金会;
关键词
GIANT MAGNETORESISTANCE; OSCILLATIONS; EXCHANGE;
D O I
10.1016/j.carbon.2009.04.048
中图分类号
O64 [物理化学(理论化学)、化学物理学];
学科分类号
070304 ; 081704 ;
摘要
Spin valves made of nanotubes contacted to magnetic electrodes may display significant values of magnetoresistance but are limited by the restricted capacity for spin injection into the tube and by the unwanted spin-flip scattering caused by magnetic impurities. We propose an alternative route to produce the spin-valve effect which (a) does not involve magnetic electrodes, avoiding the spin injection limitation, and (b) uses magnetically coupled impurities to generate an efficient spin filter that enhances the magnetoresistance by orders of magnitude. Furthermore, we predict that substitutional Mn impurities on metallic nanotubes will generate enormously large values of magnetoresistance. (C) 2009 Elsevier Ltd. All rights reserved.
引用
收藏
页码:2533 / 2537
页数:5
相关论文
共 50 条
  • [21] In-situ Lorentz microscopy studies of spin-valve structures
    Petford-Long, AK
    Portier, X
    Tsymbal, EY
    Anthony, TC
    Brug, JA
    IEEE TRANSACTIONS ON MAGNETICS, 1999, 35 (02) : 788 - 793
  • [22] Heat generation by electronic current in a quantum dot spin-valve
    Chi, Feng
    Sun, Lian-Liang
    Guo, Yu
    JOURNAL OF APPLIED PHYSICS, 2014, 116 (16)
  • [23] Simulation of Magnetic Properties of Different Types of Spin-Valve Nanostructures
    Drovorub, E. V.
    Prudnikov, P. V.
    Prudnikov, V. V.
    PHYSICS OF METALS AND METALLOGRAPHY, 2023, 124 (14) : 1662 - 1670
  • [24] Influence of an interface domain wall on spin-valve giant magnetoresistance
    Hauet, T.
    Montaigne, F.
    Hehn, M.
    Henry, Y.
    Mangin, S.
    APPLIED PHYSICS LETTERS, 2008, 93 (22)
  • [25] Performance of metallic antiferromagnets for use in spin-valve read sensors
    Lederman, M
    IEEE TRANSACTIONS ON MAGNETICS, 1999, 35 (02) : 794 - 799
  • [26] Multilayer spin-valve CoFeP/Cu nanowires with giant magnetoresistance
    Sharko, S. A.
    Serokurova, A. I.
    Zubar, T. I.
    Trukhanov, S. V.
    Tishkevich, D. I.
    Samokhvalov, A. A.
    Kozlovskiy, A. L.
    Zdorovets, M. V.
    Panina, L. V.
    Fedosyuk, V. M.
    Trukhanov, A. V.
    JOURNAL OF ALLOYS AND COMPOUNDS, 2020, 846 (846)
  • [27] Magnetotransport properties of spin-valve structures with Mg spacer layers
    Martinez-Boubeta, C.
    Ferrante, Y.
    Parkin, S. S. P.
    APPLIED PHYSICS LETTERS, 2015, 106 (03)
  • [28] Spin-Valve based magnetoresistive nanoparticle detector for applications in biosensing
    Qiu, Wenlan
    Chang, Long
    Liang, Yu-Chi
    Litvinov, Julia
    Guo, Jing
    Chen, Yi-Ting
    Vu, Binh
    Kourentzi, Katerina
    Xu, Shoujun
    Lee, T. Randall
    Zu, Youli
    Willson, Richard C.
    Litvinov, Dmitri
    SENSORS AND ACTUATORS A-PHYSICAL, 2017, 265 : 174 - 180
  • [29] Multiplemagnetic States in a Patterned Spin-Valve Thin-Film
    Nam, Chunghee
    JOURNAL OF NANOSCIENCE AND NANOTECHNOLOGY, 2017, 17 (10) : 7335 - 7338
  • [30] Design, fabrication, and analysis of a spin-valve based current sensor
    Reig, C
    Ramírez, D
    Silva, F
    Bernardo, J
    Freitas, P
    SENSORS AND ACTUATORS A-PHYSICAL, 2004, 115 (2-3) : 259 - 266
12345