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Books on the topic 'Molecules - Magnetic properties'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 February 2022

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1

Molecular magnetism. New York, NY: VCH, 1993.

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2

Molecular magnetochemistry. Amsterdam: Gordon and Breach Science Publishers, 1998.

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3

Naaman, Ron. Electronic and Magnetic Properties of Chiral Molecules and Supramolecular Architectures. Berlin, Heidelberg: Springer-Verlag Berlin Heidelberg, 2011.

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4

Supin kagaku ga hiraku bunshi jisei no shintenkai: Sekkei kara kinōka made. Kyōto-shi: Kagaku Dōjin, 2014.

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5

1903-, Arbuzov Boris Aleksandrovich, ed. Molekuli͡a︡rnai͡a︡ magnetokhimii͡a︡. Moskva: "Nauka", 1991.

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6

ICMM 2004 (2004 Tsukuba International Congress Center). The IXth International Conference on Molecule-Based Magnets, ICMM 2004: October 4-8, 2004, Tsukuba International Congress Center, Tsukuba, Japan. Japan: s.n., 2004.

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7

Naaman, Ron, David N. Beratan, and David Waldeck, eds. Electronic and Magnetic Properties of Chiral Molecules and Supramolecular Architectures. Berlin, Heidelberg: Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-642-18104-7.

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8

Buckingham, A. D. Optical, electric, and magnetic properties of molecules: A review of the work of A.D. Buckingham. Amsterdam: Elsevier, 1997.

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9

Roberta, Sessoli, and Villain Jacques, eds. Molecular nanomagnets. New York: Oxford University Press, 2006.

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10

NATO Advanced Research Workshop on Magnetic Molecular Materials (1990 Il Ciocco, Italy). Magnetic molecular materials. Dordrecht: Kluwer Academic Publishers, 1991.

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11

W, Munn Robert, ed. Magnetism and optics of molecular crystals. Chichester, England: J. Wiley, 1992.

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12

Molecular cluster magnets. Singapore: World Scientific Publishing, 2012.

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13

Albert, Furrer, ed. Frontiers of neutron scattering: Proceedings of the Seventh Summer School on Neutron Scattering, Zuoz, Switzerland, 7-13 August 1999. Singapore: World Scientific, 2000.

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14

Molecular materials. Hoboken, N.J: Wiley, 2010.

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15

Bruce, Duncan W., Dermot O'Hare, and Richard I. Walton. Molecular materials. Hoboken, N.J: Wiley, 2010.

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16

1945-, Švec Petr, Idzikowski Bogdan, Miglierini Marcel, and North Atlantic Treaty Organization. Scientific Affairs Division., eds. Properties and applications of nanocrystalline alloys from amorphous precursors. Dordrecht: Kluwer Academic Publishers, 2005.

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17

(Editor), Joel S. Miller, and Marc Drillon (Editor), eds. Magnetism, Nanosized Magnetic Materials (Magnetism: Molecules to Materials). Wiley-VCH, 2002.

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18

(Editor), Joel S. Miller, and Marc Drillon (Editor), eds. Magnetism, Molecule-Based Materials (Magnetism: Molecules to Materials). Wiley-VCH, 2001.

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19

Molecular Magnetism: New Magnetic Materials. CRC, 2000.

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20

Koichi, Itoh, and Kinoshita Minoru, eds. Molecular magnetism: New magnetic materials. Tokyo: Kodansha, 2000.

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21

(Editor), Joel S. Miller, and Marc Drillon (Editor), eds. Magnetism: Molecules to Materials IV (Magnetism: Molecules to Materials). Wiley-VCH, 2003.

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22

Buckingham, Amyand David. Optical, Electrical and Magnetic Properties of Molecules. Chapman & Hall, 1987.

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23

Optical, Electric and Magnetic Properties of Molecules. Elsevier, 1997. http://dx.doi.org/10.1016/b978-0-444-82596-4.x5009-x.

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24

S, Miller Joel, and Drillon Marc, eds. Magnetism: Molecules to materials. Weinheim: Wiley-VCH, 2001.

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25

Theoretical and Computational Aspects of Magnetic Organic Molecules. World Scientific Publishing Co Pte Ltd, 2014.

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26

Graaf, Coen de, and Ria Broer. Magnetic Interactions in Molecules and Solids. Springer, 2016.

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27

1956-, Turnbull Mark M., Sugimoto Toyonari 1945-, Thompson Laurence K. 1943-, American Chemical Society. Division of Inorganic Chemistry., and International Chemical Congress of Pacific Basin Societies (1995 : Honolulu, Hawaii), eds. Molecule-based magnetic materials: Theory, techniques, and applications. Washington, DC: American Chemical Society, 1996.

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28

Jaume, Veciana, and Arčon D, eds. [Pi]-electron magnetism: From molecules to magnetic materials. Berlin: Springer, 2001.

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29

Launay, Jean-Pierre, and Michel Verdaguer. Electrons in Molecules. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198814597.001.0001.

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The book treats in a unified way electronic properties of molecules (magnetic, electrical, photophysical), culminating with the mastering of electrons, i.e. molecular electronics and spintronics and molecular machines. Chapter 1 recalls basic concepts. Chapter 2 describes the magnetic properties due to localized electrons. This includes phenomena such as spin cross-over, exchange interaction from dihydrogen to extended molecular magnetic systems, and magnetic anisotropy with single-molecule magnets. Chapter 3 is devoted to the electrical properties due to moving electrons. One considers first electron transfer in discrete molecular systems, in particular in mixed valence compounds. Then, extended molecular solids, in particular molecular conductors, are described by band theory. Special attention is paid to structural distortions (Peierls instability) and interelectronic repulsions in narrow-band systems. Chapter 4 treats photophysical properties, mainly electron transfer in the excited state and its applications to photodiodes, organic light emitting diodes, photovoltaic cells and water photolysis. Energy transfer is also treated. Photomagnetism (how a photonic excitation modifies magnetic properties) is introduced. Finally, Chapter 5 combines the previous knowledge for three advanced subjects: first molecular electronics in its hybrid form (molecules connected to electrodes acting as wires, diodes, memory elements, field-effect transistors) or in the quantum computation approach. Then, molecular spintronics, using, besides the charge, the spin of the electron. Finally the theme of molecular machines is presented, with the problem of the directionality control of their motion.
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30

Kelly, Roxanne May Hulet. Studies directed toward the synthesis of molecular magnets. 2001.

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31

(Editor), Mark M. Turnbull, Toyonari Sugimoto (Editor), and Lawrence K. Thompson (Editor), eds. Molecule-Based Magnetic Materials: Theory, Techniques, and Applications (Acs Symposium Series). An American Chemical Society Publication, 1998.

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32

Naaman, Ron, David N. Beratan, and David Waldeck. Electronic and Magnetic Properties of Chiral Molecules and Supramolecular Architectures. Springer, 2013.

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33

W, Linert, and Verdaguer Michel, eds. Molecular magnets: Recent highlights. Wien: Springer, 2003.

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34

Eugenio, Coronado, ed. Molecular magnetism: From molecular assemblies to the devices. Dordrecht: Kluwer Academic, 1996.

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35

López Ruiz, Román. Magnetic properties of mesoscopic-size materials : from molecules to nanowires. Prensas Universitarias de Zaragoza, 2009. http://dx.doi.org/10.26754/uz.978-84-92521-78-4.

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36

Winpenny, Richard. Single-Molecule Magnets and Related Phenomena (Structure and Bonding). Springer, 2006.

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37

Kozlova, Svetlana G., and Svyatoslav P. Gabuda. Spin-Orbit Interactions in PtF6 and in Related Octahedral Molecules and Fluorocomplexes. Nova Science Publishers, Incorporated, 2010.

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38

(Contributor), D. Arcon, M. Deumal (Contributor), K. Inoue (Contributor), M. Kinoshita (Contributor), J. J. Novoa (Contributor), F. Palacio (Contributor), K. Prassides (Contributor), J. M. Rawson (Contributor), C. Rovira (Contributor), and Jaume Veciana (Editor), eds. Electron Magnetism (Structure and Bonding). Springer, 2001.

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39

Launay, Jean-Pierre, and Michel Verdaguer. The excited electron: photophysical properties. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198814597.003.0004.

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After a review of fundamental notions such as absorption, emission and the properties of excited states, the chapter introduces excited-state electron transfer. Several examples are given, using molecules to realize photodiodes, light emitting diodes, photovoltaic cells, and even harnessing photochemical energy for water photolysis. The specificities of ultrafast electron transfer are outlined. Energy transfer is then defined, starting from its theoretical description, and showing its involvement in photonic wires or molecular assemblies realizing an antenna effect for light harvesting. Photomagnetic effects; that is, the modification of magnetic properties after a photonic excitation, are then studied. The examples are taken from systems presenting a spin cross-over, with the LIESST effect, and from systems presenting metal–metal charge transfer, in particular in Prussian Blue analogues and their molecular version.
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40

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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41

Wernsdorfer, W. Molecular nanomagnets. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.4.

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This article describes the quantum phenomena observed in molecular nanomagnets. Molecular nanomagnets, or single-molecule magnets (SMMs), provides a fundamental link between spintronics and molecular electronics. SMMs combine the classic macroscale properties of a magnet with the quantum properties of a nanoscale entity. The resulting field, molecular spintronics, aims at manipulating spins and charges in electronic devices containing one or more molecules. This article first considers molecular nanomagnets and the giant spin model for nanomagnets before discussing the quantum dynamics of a dimer of nanomagnets, resonant photon absorption in Cr7Ni antiferromagnetic rings, and photon-assisted tunnelling in a single-molecule magnet. It also examines environmental decoherence effects in nanomagnets and concludes by highlighting the new trends towards molecular spintronics using junctions and nano-SQUIDs.
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42

Seco, Josi M., Emilio Quiqoa, and Ricardo Riguera. The Assignment of the Absolute Configuration by NMR using Chiral Derivatizing Agents. Oxford University Press, 2015. http://dx.doi.org/10.1093/oso/9780199996803.001.0001.

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Nuclear magnetic resonance spectroscopy (NMR spectroscopy) is a research technique that uses the magnetic properties of atomic nuclei to determine physical and chemical properties of atoms or the molecules in which they are contained. Proton NMR (1H NMR) is a technique that applies NMR spectroscopy specifically to the hydrogen-1 nuclei within the molecules of a substance, in order to determine the structure of that substance's molecules. The use of 1H NMR for the assignment of absolute configuration of organic compounds is a well-established technique. Recent research describes the technique's application to mono-, bi- and trifunctional compounds. In addition, several new auxiliary reagents, mono- and biderivatization procedures, on-resin methodologies and more recently, the use of 13C NMR, have been introduced to the field. In The Assignment of the Absolute Configuration by NMR Using Chiral Derivatizing Agents: A Practical Guide, eminent Professor of Organic Chemistry Ricardo Riguera organizes this cutting-edge NMR research. Professor Riguera offers a short and usable guide that introduces the reader to the research with a plethora of details and examples. The book briefly explains the theoretical aspects necessary for understanding the methodology, dedicating most of its space to covering the practical aspects of the assignment, with examples and spectra taken from the authors' own experiments. Upper-level undergraduates, graduate students, and chemical researchers will find this guide useful for their studies and practice.
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43

Furrer, Albert, and Summer School on Neutron Scattering 1999. Frontiers of Neutron Scattering: Proceedings of the Seventh Summer School on Neutron Scattering, Zuoz, Switzerland, 7-13 August 1999. World Scientific Publishing Company, 2000.

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44

Launay, Jean-Pierre, and Michel Verdaguer. The moving electron: electrical properties. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198814597.003.0003.

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The three basic parameters controlling electron transfer are presented: electronic interaction, structural change and interelectronic repulsion. Then electron transfer in discrete molecular systems is considered, with cases of inter- and intramolecular transfers. The semi-classical (Marcus—Hush) and quantum models are developed, and the properties of mixed valence systems are described. Double exchange in magnetic mixed valence entities is introduced. Biological electron transfer in proteins is briefly presented. The conductivity in extended molecular solids (in particular organic conductors) is tackled starting from band theory, with examples such as KCP, polyacetylene and TTF-TCNQ. It is shown that electron–phonon interaction can change the geometrical structure and alter conductivity through Peierls distortion. Another important effect occurs in narrow-band systems where the interelectronic repulsion plays a leading role, for instance in Mott insulators.
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45

Bruce, Duncan W., Dermot O'Hare, and Richard I. Walton. Molecular Materials. Wiley & Sons, Incorporated, John, 2011.

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46

Bruce, Duncan W., Dermot O'Hare, and Richard I. Walton. Molecular Materials. Wiley & Sons, Incorporated, John, 2010.

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47

Bruce, Duncan W., Dermot O'Hare, and Richard I. Walton. Molecular Materials. Wiley & Sons, Incorporated, John, 2011.

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48

Bi, J. F., and K. L. Teo. Nanoscale Ge1−xMnxTe ferromagnetic semiconductors. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.17.

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This article discusses the structure characterizations, magnetic and transport behaviors of the nanoscale ferromagnetic semiconductors Ge1-xMnxTe grown by molecular beam epitaxy with various manganese compositions x ranging from 0.14 to 0.98. After providing an overview of the growth procedure and characterization, the article analyzes the structures of the Ge1-xMnxTe system using X-ray diffraction and high-resolution transmission electron microscopy. It then considers the optical, magnetic and transport properties of the semiconductors and shows that the crystal quality is degraded and the proportion of amorphous phase increases with increasing Mn composition. Nanoclusters and nanoscale grains can be observed when x > 0.24, which greatly affect their magnetic and electronic properties. The magnetic anisotropy is weakened due to different orientations of the clusters embedded in the GeTe host. An anomalous Hall effect is also observed in the samples, which can be attributed to extrinsic skew scattering.
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49

Furst, Eric M., and Todd M. Squires. Active microrheology. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199655205.003.0007.

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Active microrheology uses external forces (most typically magnetic or optical) to force microrheological probes into motion. These techniques short-circuit the Einstein component of passive microrheology. Active microrheology provides an additional handle to probe material properties, and has been used both to extend the range of materials amenable to microrheological analysis, and to examine material properties that are inaccessible to passive microrheology. Three main topics are presented: the use of active microrheology to extend the range of passive microrheology, while maintaining many of the advantages (small sample size, wide frequency range, etc.); its use to complement passive microrheology in active systems, which convert chemical fuel to mechanical work, in order to elucidate the power provided by molecular motors, for instance; and its application (and potential limitations) to investigate the non-linear response properties of materials, including shear thinning and yielding.
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50

(Editor), Bogdan Idzikowski, Peter Svec (Editor), and Marcel Miglierini (Editor), eds. Properties and Applications of Nanocrystalline Alloys from Amorphous Precursors. Springer, 2005.

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