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Books on the topic 'Magnetic anisotrophy'

Author: Grafiati
Published: 18 May 2024

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1

Porter, Eithne Mary. Anisotrophy of magnetic susceptibility in the Criffel-Dalbeattie pluton, Scotland: Implications for emplacement mechanism. Birmingham: University of Birmingham, 2002.

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2

Tarling, D. H. The magnetic anisotropy of rocks. London: Chapman & Hall, 1993.

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3

F, Martín-Hernández, and Geological Society of London, eds. Magnetic fabric: Methods and applications. London: Geological Society, 2004.

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4

Hussain, T. Magnetic anisotropy studies of TbFe thin films. Salford: University of Salford, 1990.

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5

Greer, Allan J., and William J. Kossler. Low Magnetic Fields in Anisotropic Superconductors. Berlin, Heidelberg: Springer Berlin Heidelberg, 1995. http://dx.doi.org/10.1007/978-3-540-49214-6.

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6

Greer, Allan J. Low magnetic fields in anisotropic superconductors. Heidelberg, Germany: Springer, 1995.

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7

Satter, Md Abdus. A theory for dilute magnetic alloys: The origin of magnetic anisotropy. [s.l.]: typescript, 1989.

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8

Gupta, R. R., ed. Diamagnetic Susceptibility and Magnetic Anisotropy of Organic Compounds. Berlin, Heidelberg: Springer Berlin Heidelberg, 2008. http://dx.doi.org/10.1007/978-3-540-44736-8.

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9

Fujita, Akira. A study on magnetic anisotropy induced in the HDDR process. Birmingham: University of Birmingham, 1999.

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10

Weinberger, P. Magnetic anisotropies in nanostructured matter. Boca Raton: Taylor & Francis, 2009.

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11

Mazgaj, Witold. Wyznaczanie rozkładu pola magnetycznego w materiałach magnetycznie miękkich z uwzględnieniem histerezy i anizotropii: Calculation of magnetic field distribution in soft magnetic materials taking into account hysteresis and anisotropy = [Raschet raspredelenii︠a︡ magnitnogo poli︠a︡ v magnitno-mi︠a︡gkikh materialakh s uchetom gisterezisa i anizotropii]. Kraków: Wydawnictwo PK, 2010.

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12

L, Reynolds Richard, Meyer Robert, and Geological Survey (U.S.), eds. Paleomagnetism of Pleistocene sediments from drill hole OL-92, Owens Lake, California: Reevaluation of magnetic excursions using anisotropy of magnetic susceptibility. Denver, Colo: U.S. Dept. of the Interior, U.S. Geological Survey, 1998.

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13

International Symposium on Magnetic Anisotropy and Coercivity in Rare-Earth Transition Metal Alloys (10th : 1998 : Dresden, Germany). Magnetic anisotropy and coercivity in rare-earth transition metal alloys: Proceedings of the Tenth International Symposium on Magnetic Anisotropy and Coercivity in Rare-Earth Transition Metal Alloys, 4 September 1998, Dresden, Germany. Frankfurt, Germany: Werkstoff-Informationsgesellschaft, 1998.

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14

Emerson, D. W. Magnetic exploration models, incorporating remanence, demagnetization and anisotropy HP 41C handheld computer algorithms. Melbourne: Blackwell Scientific Publications, 1985.

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15

Gefügeuntersuchungen an Amphiboliten der Böhmischen Masse unter besonderer Berücksichtigung der Anisotropie der magnetischen Suszeptibilität. Stuttgart: E. Schweizerbart, 1995.

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16

A, Serdi͡ukov, ed. Electromagnetics of bi-anisotropic materials: Theory and applications. Australia: Gordon and Breach Science, 2001.

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17

Elliott, Burnell E., and De Lange Cornelis A, eds. NMR of ordered liquids. Dordrecht: Kluwer Academic Publishers, 2003.

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18

P, Missell F., Fundação de Amparo à Pesquisa do Estado de São Paulo., International Workshop on Rare-Earth Magnets and Their Applications (14th : 1996 : São Paulo, Brazil), and International Symposium on Magnetic Anisotropy and Coercivity in Rare-Earth-Transition Metal Alloys (9th : 1996 : São Paulo, Brazil), eds. Proceedings of the 14th International Workshop Rare-Earth Magnets and Their Applications: São Paulo, Brazil, 1-4 September 1996. Singapore: World Scientific, 1996.

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19

L, Schultz, and Müller K. -H, eds. Rare-earth magnets and their applications: Proceedings of the Fifteenth International Workshop on Rare-Earth Magnets and Their Applications, 30 August-3 September 1998, Dresden, Germany. Frankfurt: Mat Info/Werkstoff-Informationsgesellschaft, 1998.

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20

Haley, Richard Peter. NMR investigation of the magnetic susceptibility anisotropy in the A phase of 3He. Manchester: University of Manchester, 1995.

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21

Eroglu, Abdullah. Wave Propagation and Radiation in Gyrotropic and Anisotropic Media. Boston, MA: Springer Science+Business Media, LLC, 2010.

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22

Burton, J. D., and E. Y. Tsymbal. Magnetoresistive phenomena in nanoscale magnetic contacts. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533046.013.18.

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This article examines magnetoresistive phenomena in nano- and atomic-size ferromagnetic metal contacts. In particular, it considers how magnetization affects the flow of electrical current in ferromagnetic materials by focusing on two major categories of magnetoresistive phenomena: the ‘spin-valve’, where the flow of spin-polarized electrical current is affected by an inhomogeneous magnetization profile, and anisotropic magnetoresistance (AMR), which involves the anisotropy of electrical transport properties with respect to the orientation of the magnetization. The article first provides an overview of ballistic transport and conductance quantization before discussing domain-wall magnetoresistance at the nanoscale. It also describes AMR in magnetic nanocontacts as well as tunnelling anisotropic magnetoresistance in broken contacts.
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23

Launay, Jean-Pierre, and Michel Verdaguer. The localized electron: magnetic properties. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198814597.003.0002.

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After preliminaries about electron properties, and definitions in magnetism, one treats the magnetism of mononuclear complexes, in particular spin cross-over, showing the role of cooperativity and the sensitivity to external perturbations. Orbital interactions and exchange interaction are explained in binuclear model systems, using orbital overlap and orthogonality concepts to explain antiferromagnetic or ferromagnetic coupling. The phenomenologically useful Spin Hamiltonian is defined. The concepts are then applied to extended molecular magnetic systems, leading to molecular magnetic materials of various dimensionalities exhibiting bulk ferro- or ferrimagnetism. An illustration is provided by Prussian Blue analogues. Magnetic anisotropy is introduced. It is shown that in some cases, a slow relaxation of magnetization arises and gives rise to appealing single-ion magnets, single-molecule magnets or single-chain magnets, a route to store information at the molecular level.
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24

Fremont, Georges. Closer Look at Magnetic Anisotropy. Nova Science Publishers, Incorporated, 2020.

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25

Fremont, Georges. Closer Look at Magnetic Anisotropy. Nova Science Publishers, Incorporated, 2020.

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26

Eriksson, Olle, Anders Bergman, Lars Bergqvist, and Johan Hellsvik. Ferromagnetic Resonance. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198788669.003.0008.

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In the previous chapters we covered theoretical aspects of magnetism and magnetization dynamics, as well as practical aspects of implementation of the SLL equation in efficient softwares. In this chapter we focus on the most natural and frequently used experimental method to study magnetization dynamics, namely ferromagnetic resonance (FMR). This experimental technique has evolved into a powerful experimental technique for studies of magnetization dynamics of materials. It is, by far, the most common method for extracting damping parameters in materials, and is also a reliable technique for estimating precession frequencies of magnetic systems, leading to detection of magnetic g-factor, magnetic anisotropy and saturation magnetism.
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27

Ferre, Eric, and Anne Hirt. Magnetic Anisotropy of Minerals and Rocks. Wiley & Sons, Limited, John, 2019.

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28

Lu, Chung. Magnetic anisotropy in Ni/V superlattices. 1987.

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29

Ferre, Eric, and Anne Hirt. Magnetic Anisotropy of Minerals and Rocks. Wiley & Sons, Limited, John, 2019.

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30

Schneider, Gunter. Calculation of magnetocrystalline anisotropy. 1998.

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31

al, et. Magnetic Fabric: Methods and Applications. Geological Society of London, 2005.

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32

Kossler, William J., and Allan J. Greer. Low Magnetic Fields in Anisotropic Superconductors. Springer London, Limited, 2008.

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33

Kossler, William J., and Allan J. Greer. Low Magnetic Fields in Anisotropic Superconductors. Springer Berlin / Heidelberg, 2014.

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34

Strouse, Gregory Fielding. Magnetic anisotropy and magnetization of Mo/Ni superlattices. 1986.

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35

Patyal, Baldev Raj. An electron paramagnetic resonance (EPR) study of magnetic anisotropies in one-and two-dimensional copper(II) magnetic insulators. 1988, 1988.

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36

Eriksson, Olle, Anders Bergman, Lars Bergqvist, and Johan Hellsvik. Applications of Density Functional Theory. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198788669.003.0003.

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In this chapter we give examples of how density functional theory describes some of the most basic magnetic properties of a material. This involves spin and orbital moments, Heisenberg exchange parameters and magnetic form factors. Relativistic effects couple spin and orbital space and make magnetic materials anisotropic, which means that the ground state magnetization is oriented parallel or perpendicular to high symmetry directions of the crystalline structure. We also illustrate how well density functional theory describes cohesive properties and how magnetism influence these properties. These examples serve to give a general picture of how well density functional theory, as described in the previous chapters, can reproduce relevant features of magnetic materials, as well as to illustrate that the onset of spin-polarization can have drastic influence on all properties of a material.
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37

Kumar, Mahendra, and Rajni Gupta. Diamagnetic Susceptibility and Anisotropy SubVol. C: Diamagnetic Susceptibility and Magnetic Anisotropy of Organic Compounds. Springer Berlin / Heidelberg, 2008.

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38

O'Brien, Alexandra V. A ferromagnetic resonance study of the magnetic anisotropies and interlayer coupling of Co/Cr trilayers. 1997.

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39

Mørup, Steen, Cathrine Frandsen, and Mikkel F. Hansen. Magnetic properties of nanoparticles. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.20.

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This article discusses the magnetic properties of nanoparticles. It first considers magnetic domains and the critical size for single-domain behavior of magnetic nanoparticles before providing an overview of magnetic anisotropy in nanoparticles. It then examines magnetic dynamics in nanoparticles, with particular emphasis on superparamagnetic relaxation and the use of Mössbauer spectroscopy, dc magnetization measurements, and ac susceptibility measurements for studies of superparamagnetic relaxation. It also describes magnetic dynamics below the blocking temperature, magnetic interactions between nanoparticles, and fluctuations of the magnetization directions. Finally, it analyzes the magnetic structure of nanoparticles, focusing on magnetic phase transitions and surface effects, non-collinear spin structures, and magnetic moments of antiferromagnetic nanoparticles.
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40

Runge, Alan Paul. Magnetic multilayer anisotropy investigated with a variable temperature torque magnetometer. 1991.

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41

Magnetic anisotropy and coercivity in rare-earth transition metal alloys: Proceedings of the Tenth International Symposium on Magnetic Anisotropy and Coercivity ... Alloys, 4 September 1998, Dresden, Germany. Werkstoff-Informationsgesellschaft, 1998.

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42

Wang, Haiyan. Relation between bandstructure and magnetocrystalline anisotropy: Iron and nickel. 2000.

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43

Weinberger, P. Magnetic Anisotropies in Nanostructured Matter. Taylor & Francis Group, 2008.

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44

Weinberger, P., and P. Weinberger. Magnetic Anisotropies in Nanostructured Matter. Taylor & Francis Group, 2008.

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45

Compton, Robert L. Ferromagnetic resonance study of the magnetic anisotropy of a bilayer of Fe on FePtp3s. 2001.

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46

Weinberger, P. Magnetic Anisotropies in Nanostructured Matter. Taylor & Francis Group, 2008.

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47

Magnetic Anisotropies in Nano-Structured Matter. Chapman & Hall/CRC, 2008.

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48

Paleomagnetism of Pleistocene sediments from drill hole OL-92, Owens Lake, California: Reevaluation of magnetic excursions using anisotropy of magnetic susceptibility. Denver, Colo: U.S. Dept. of the Interior, U.S. Geological Survey, 1998.

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49

Paleomagnetism of Pleistocene sediments from drill hole OL-92, Owens Lake, California: Reevaluation of magnetic excursions using anisotropy of magnetic susceptibility. Denver, Colo: U.S. Dept. of the Interior, U.S. Geological Survey, 1998.

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50

Pirota, Kleber Roberto, Angela Knobel, Manuel Hernandez-Velez, Kornelius Nielsch, and Manuel Vázquez. Magnetic nanowires: Fabrication and characterization. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.22.

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This article describes the fabrication and characterization of magnetic nanowires, focusing on the magnetic properties of patterned arrays of metallic magnetic nanowires electrodeposited into the pores of anodized-alumina membranes. It also discusses the complex magnetization processes, both in isolated nanowires and in collectively patterned arrays. After providing an overview of the state-of-the-art on fabrication techniques of nanowires, the article considers the microstructure of magnetic nanowires and the magnetic properties of single nanowires. It then examines the collective behavior of arrays where the interactions among the magnetic entities play an important role, along with the transport properties of magnetic nanowires, the temperature-dependent effects (such as magnetoelastic-induced anisotropy), and the dynamic properties of magnetization such as ferromagnetic resonance characteristics and spin-wave excitations in ferromagnetic nanowires. Finally, it presents an overview of future research directions.
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