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Books on the topic 'Magnetic carbon'

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Published: 7 September 2022
Last updated: 18 September 2022

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1

Levy, George C. Carbon-13 nuclear magnetic resonance spectroscopy. 2nd ed. Malabar, Fla: Krieger, 1993.

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2

Levy, George C. Carbon-13 nuclear magnetic resonance spectroscopy. Malabar, Fla: Krieger Pub. Co., 1992.

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3

Carbon-13 NMR spectroscopy. Chichester: Wiley, 1988.

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4

Berliner, L. J. Biological Magnetic Resonance, Volume 15: In vivo Carbon-13 NMR. Dordrecht: Springer, 1999.

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5

Yeo, Reuben Jueyuan. Ultrathin Carbon-Based Overcoats for Extremely High Density Magnetic Recording. Singapore: Springer Singapore, 2017. http://dx.doi.org/10.1007/978-981-10-4882-1.

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6

Breitmaier, E. Carbon-13 NMR spectroscopy: High-resolution methods and applications in organic chemistry and biochemistry. 3rd ed. New York: VCH Publishers, 1987.

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7

Pihlaja, Kalevi. Carbon-13 NMR chemical shifts in structural and stereochemical analysis. New York: VCH, 1994.

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8

Wehrli, F. W. Interpretation of carbon-13 NMR spectra. 2nd ed. Chichester: Wiley, 1988.

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9

Dreeskamp, Herbert. Anwendung neuer Techniken der ¹³C-NMR-Spektroskopie in der Analytik der für den Bereich der Kohlechemie typischen Stoffe. Hamburg: Deutsche Gesellschaft für Mineralölwissenschaft und Kohlechemie, 1985.

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10

Whitesell, James K. Stereochemical analysis of alicyclic compounds by C-13 NMR spectroscopy. London: Chapman and Hall, 1987.

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11

Neumann, Andreas. Electronic transport in highly resistive materials in strong magnetic fields: Nonlinear dynamics in semi-insulating GaAs and magnetoresistance of carbon-black polymer composites. Konstanz: Hartung-Gorre, 1997.

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12

Yoon, Se Young. Control of Surge in Centrifugal Compressors by Active Magnetic Bearings: Theory and Implementation. London: Springer London, 2013.

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13

Thorn, Kevin A. Characterization of the International Humic Substances Society standard and reference fulvic and humic acids by solution state carbon-13 (p13sC) and hydrogen-1 (p1sH) nuclear magnetic resonance spectrometry. Denver, Colo: U.S. Dept. of the Interior, U.S. Geological Survey, 1991.

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14

Thorn, Kevin A. Characterization of the International Humic Substances Society standard and reference fulvic and humic acids by solution state carbon-13 (C) and hydrogen-1 (H) nuclear magnetic resonance spectrometry. Denver, Colo: U.S. Dept. of the Interior, U.S. Geological Survey, 1991.

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15

Born, R. Ab initio calculations of conformational effects on ¹³C NMR spectra of amorphous polymers. Berlin: Springer, 1997.

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16

Nyquist, Richard A. IR and NMR spectral data-structure correlations for the carbonyl group. Philadelphia, Pa: Sadtler Research Laboratories, 1986.

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17

ZnO bao mo zhi bei ji qi guang, dian xing neng yan jiu. Shanghai Shi: Shanghai da xue chu ban she, 2010.

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18

Hagelberg, Frank B. Magnetism in Carbon Nanostructures. Cambridge University Press, 2017.

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19

(Editor), Lawrence J. Berliner, and Pierre-Marie Robitaille (Editor), eds. Biological Magnetic Resonance: Volume 15: In vivo Carbon-13 NMR (Biological Magnetic Resonance). Springer, 1999.

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20

Andriotis, A. N., R. M. Sheetz, E. Richter, and M. Menon. Structural, electronic, magnetic, and transport properties of carbon-fullerene-based polymers. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.21.

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This article discusses the structural, electronic, magnetic, and transport properties of carbon-fullerene-based polymers. In particular, it examines the defect-induced ferromagnetism of the C60-based polymers and its analog in the case of non-traditional inorganic materials. It first reviews the computational methods currently used in the literature, highlighting the pros and cons of each one of them. It then considers the defects associated with the ferromagnetism of the C60-based polymers, namely carbon vacancies, the 2 + 2 cycloaddition bonds and impurity atoms, and their effect on the electronic structure. It also evaluates the effect of codoping and goes on to describe the electronic, magnetic and transport properties of the rhombohedral C60-polymer. Finally, it looks at the origin of magnetic coupling among the magnetic moments in the rhombohedral C60-polymer and provides further evidence for the analogy between the magnetism of the rhombohedral C60-polymer and zinc oxide.
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21

Kumar, Challa Vijaya. Nanoarchitectures Built with Carbon Nanotubes and Magnetic Nanoparticles. Elsevier Science & Technology Books, 2020.

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22

Kumar, Challa Vijaya. Nanoarchitectures Built with Carbon Nanotubes and Magnetic Nanoparticles. Elsevier Science & Technology, 2020.

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23

Hyperpolarized Carbon-13 Magnetic Resonance Imaging and Spectroscopy. Elsevier, 2021. http://dx.doi.org/10.1016/c2019-0-04183-0.

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24

(Editor), Tatiana Makarova, and Fernando Palacio (Editor), eds. Carbon Based Magnetism: An Overview of the Magnetism of Metal Free Carbon-based Compounds and Materials. Elsevier Science, 2006.

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25

Tatiana, Makarova, and Palacio Parada Fernando, eds. Carbon-based magnetism: An overview of the magnetism of metal free carbon-based compounds and materials. Amsterdam: Elsevier, 2006.

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26

1946-, Botto Robert E., Sanada Yūzō 1932-, and International Chemical Congress of Pacific Basin Societies (1989 : Honolulu, Hawaii), eds. Magnetic resonance of carbonaceous solids. Washington, D.C: American Chemical Society, 1993.

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27

Nanoarmoring of Enzymes with Carbon Nanotubes and Magnetic Nanoparticles. Elsevier, 2020. http://dx.doi.org/10.1016/s0076-6879(20)x0002-4.

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28

Tho, Pham Quang, and Pham Quang Tho, eds. Proton and carbon NMR spectra of polymers. 5th ed. Chichester, West Sussex, England: Wiley, 2003.

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29

K, Agrawal P., ed. Carbon-13 NMR of flavonoids. Amsterdam: Elsevier, 1989.

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30

Breitmaier, E. Atlas of Carbon-13 NMR Data. Springer, 2013.

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31

Yeo, Reuben Jueyuan. Ultrathin Carbon-Based Overcoats for Extremely High Density Magnetic Recording. Springer, 2018.

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32

Tho, Pham Quang, and Pham Quang Tho, eds. Proton and carbon NMR spectra of polymers. London: Penton Press, 1991.

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33

Carbon-13 NMR spectroscopy of biological systems. San Diego: Academic Press, 1995.

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34

(Firm), Occidental Chemical, ed. Carbon-13 NMR spectra of polyimide monomers. [United States]: OXY, 1991.

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35

C₂₄₀--the most chemically inert fullerene? [New York]: Elsevier, 1997.

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36

E, Scuseria G., Smalley R. E, and United States. National Aeronautics and Space Administration., eds. C₂₄₀--the most chemically inert fullerene? [New York]: Elsevier, 1997.

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37

Laboratories, Sadtler Research, ed. The Sadtler guide to carbon-13 NMR spectra of polymers and resins. Philadelphia, Pa: Sadtler, 1988.

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38

Kyotani, T., and H. Orikasa. Templated carbon nanotubes and the use of their cavities for nanomaterial synthesis. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.11.

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This article focuses on templated carbon nanotubes (CNTs) and how their cavities can be used for the synthesis of nanomaterials. In particular, it demonstrates how effectively the CNTs can be functionalized by the template carbonization technique. The article first describes the method for synthesizing CNTs and carbon nano-test-tubes (CNTTs). It then considers the controlled filling of magnetic materials into CNTTs, taking into account the electrochemical deposition of Ni-Fe alloy and the magnetic properties of NiFe-filled CNTTs. It also examines the synthesis of water-dispersible and magnetically responsive CNTTs, with emphasis on water dispersibility and the effect of magnetic interaction. Finally, it shows how the cavities of templated CNTs can be utilized as a reaction field for the hydrothermal synthesis of one-dimensional nanomaterials.
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39

Essential Oils: Analysis by Capillary Gas Chromatography and Carbon 13-NMR Spectroscopy. 2nd ed. Wiley, 2002.

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40

Oshiyama, Atsushi, and Susumu Okada. Roles of shape and space in electronic properties of carbon nanomaterials. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.3.

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This article examines how internal space and boundary shapes affect the electronic properties of carbon nanomaterials by conducting total-energy electronic-structure calculations based on the density-functional theory. It first considers the existence of nanospace in carbon peapods before discussing boundaries in planar and tubular nanostructures. It also describes double-walled nanotubes, defects in carbon nanotubes, and hybrid structures of carbon nanotubes. Finally, it discusses the magnetic properties of zigzag-edged graphene ribbons and carbon nanotubes as well as the essential role of the edge state. The article shows that both space and peas (fullerenes) are decisive in electronic properties. In carbon peapods, nearly free-electron states occurring in the internal space hybridize with carbon orbitals and then make the peapod a new multicarrier system. The edge state belongs to a new class of electron states that is inherent to zigzag borders in hexagonally bonded networks.
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41

Peters, G., C. Bauhofer, and P. Weigner. Compounds with 8 to 12 Carbon Atoms (Supplement to Subvolume B and E) (Numerical Data). Springer, 2007.

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42

B, Hall William, and United States. National Aeronautics and Space Administration., eds. Nozzle Initiative Industry Advisory Committee on Standardization of Carbon-Phenolic Test Methods and Specifications: Held at Mississippi State University, Mississippi State, Mississippi, May 18-20, 1994 : final report. [Washington, DC: National Aeronautics and Space Administration, 1994.

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43

1916-, Hall William B., and United States. National Aeronautics and Space Administration., eds. Nozzle Initiative Industry Advisory Committee on Standardization of Carbon-Phenolic Test Methods and Specifications: Held at Mississippi State University, Mississippi State, Mississippi, May 18-20, 1994 : final report. [Washington, DC: National Aeronautics and Space Administration, 1994.

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44

Allaire, Paul E., Zongli Lin, and Se Young Yoon. Control of Surge in Centrifugal Compressors by Active Magnetic Bearings. Springer, 2012.

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45

Peters, G., C. Bauhofer, and P. Weigner. Compounds with 1 to 7 Carbon Atoms (Landolt-Bornstein: Numerical Data and Functional Relationships in Science and Technology - New Series). Springer, 2007.

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46

1852-1913, Börnstein R., Landolt H. 1831-1910, Martienssen W, Peters G, Sajus H, Vill V, Bauhofer C, and Weigner P, eds. Zahlenwerte und Funktionen aus Naturwissenschaften und Technik: Gesamtregister = Numerical data and functional relationships in science and technology. Berlin: Springer-Verlag, 1999.

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47

Narlikar, A. V., and Y. Y. Fu, eds. Oxford Handbook of Nanoscience and Technology. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.001.0001.

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This Handbook presents important developments in the field of nanoscience and technology, focusing on the advances made with a host of nanomaterials including DNA and protein-based nanostructures. Topics include: optical properties of carbon nanotubes and nanographene; defects and disorder in carbon nanotubes; roles of shape and space in electronic properties of carbon nanomaterials; size-dependent phase transitions and phase reversal at the nanoscale; scanning transmission electron microscopy of nanostructures; the use of microspectroscopy to discriminate nanomolecular cellular alterations in biomedical research; holographic laser processing for three-dimensional photonic lattices; and nanoanalysis of materials using near-field Raman spectroscopy. The volume also explores new phenomena in the nanospace of single-wall carbon nanotubes; ZnO wide-bandgap semiconductor nanostructures; selective self-assembly of semi-metal straight and branched nanorods on inert substrates; nanostructured crystals and nanocrystalline zeolites; unusual properties of nanoscale ferroelectrics; structural, electronic, magnetic, and transport properties of carbon-fullerene-based polymers; fabrication and characterization of magnetic nanowires; and properties and potential of protein-DNA conjugates for analytic applications.
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48

Schwitter, Juerg, and Jens Bremerich. Cardiac magnetic resonance in the intensive and cardiac care unit. Oxford University Press, 2015. http://dx.doi.org/10.1093/med/9780199687039.003.0023.

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Current applications of cardiac magnetic resonance offer a wide spectrum of indications in the setting of acute cardiac care. In particular, cardiac magnetic resonance is helpful for the differential diagnosis of chest pain by the detection of ischaemia, myocardial stunning, myocarditis, and pericarditis. Also, Takotsubo cardiomyopathy and acute aortic diseases can be evaluated by cardiac magnetic resonance and are important differential diagnoses in patients with acute chest pain. In patients with restricted windows for echocardiography, according to guidelines, cardiac magnetic resonance is the method of choice to evaluate complications of an acute myocardial infarction. In an acute myocardial infarction, cardiac magnetic resonance allows for a unique characterization of myocardial damage by quantifying necrosis, microvascular obstruction, oedema (i.e. area at risk), and haemorrhage. These features will help us to understand better the pathophysiological events during infarction and will also allow us to assess new treatment strategies in acute myocardial infarction. To which extent the information on tissue damage will guide patient management is not yet clear, and further research, e.g. in the setting of the European Cardiovascular MR registry, is ongoing to address this issue. Recent studies also demonstrated the possiblity to reduce costs in the management of acute coronary syndromes when cardiac magnetic resonance is integrated into the routine work-up. In the near future, applications of cardiac magnetic resonance will continue to expand in the acute cardiac care units, as manufacturers are now strongly focusing on this aspect of user-friendliness. Finally, in the next decade or so, magnetic resonance imaging of other nuclei, such as fluorine and carbon, might become a reality in clinics, which would allow for metabolic and targeted molecular imaging with excellent sensitivity and specificity.
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49

Schwitter, Juerg, and Jens Bremerich. Cardiac magnetic resonance in the intensive and cardiac care unit. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780199687039.003.0023_update_001.

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Current applications of cardiac magnetic resonance offer a wide spectrum of indications in the setting of acute cardiac care. In particular, cardiac magnetic resonance is helpful for the differential diagnosis of chest pain by the detection of ischaemia, myocardial stunning, myocarditis, and pericarditis. Also, Takotsubo cardiomyopathy and acute aortic diseases can be evaluated by cardiac magnetic resonance and are important differential diagnoses in patients with acute chest pain. In patients with restricted windows for echocardiography, according to guidelines, cardiac magnetic resonance is the method of choice to evaluate complications of an acute myocardial infarction. In an acute myocardial infarction, cardiac magnetic resonance allows for a unique characterization of myocardial damage by quantifying necrosis, microvascular obstruction, oedema (i.e. area at risk), and haemorrhage. These features will help us to understand better the pathophysiological events during infarction and will also allow us to assess new treatment strategies in acute myocardial infarction. To which extent the information on tissue damage will guide patient management is not yet clear, and further research, e.g. in the setting of the European Cardiovascular MR registry, is ongoing to address this issue. Recent studies also demonstrated the possiblity to reduce costs in the management of acute coronary syndromes when cardiac magnetic resonance is integrated into the routine work-up. In the near future, applications of cardiac magnetic resonance will continue to expand in the acute cardiac care units, as manufacturers are now strongly focusing on this aspect of user-friendliness. Finally, in the next decade or so, magnetic resonance imaging of other nuclei, such as fluorine and carbon, might become a reality in clinics, which would allow for metabolic and targeted molecular imaging with excellent sensitivity and specificity.
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50

Schwitter, Juerg, and Jens Bremerich. Cardiac magnetic resonance in the intensive and cardiac care unit. Oxford University Press, 2018. http://dx.doi.org/10.1093/med/9780199687039.003.0023_update_002.

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Abstract:
Current applications of cardiac magnetic resonance offer a wide spectrum of indications in the setting of acute cardiac care. In particular, cardiac magnetic resonance is helpful for the differential diagnosis of chest pain by the detection of ischaemia, myocardial stunning, myocarditis, and pericarditis. Also, Takotsubo cardiomyopathy and acute aortic diseases can be evaluated by cardiac magnetic resonance and are important differential diagnoses in patients with acute chest pain. In patients with restricted windows for echocardiography, according to guidelines, cardiac magnetic resonance is the method of choice to evaluate complications of an acute myocardial infarction. In an acute myocardial infarction, cardiac magnetic resonance allows for a unique characterization of myocardial damage by quantifying necrosis, microvascular obstruction, oedema (i.e. area at risk), and haemorrhage. These features will help us to understand better the pathophysiological events during infarction and will also allow us to assess new treatment strategies in acute myocardial infarction. To which extent the information on tissue damage will guide patient management is not yet clear, and further research, e.g. in the setting of the European Cardiovascular MR registry, is ongoing to address this issue. Recent studies also demonstrated the possiblity to reduce costs in the management of acute coronary syndromes when cardiac magnetic resonance is integrated into the routine work-up. In the near future, applications of cardiac magnetic resonance will continue to expand in the acute cardiac care units, as manufacturers are now strongly focusing on this aspect of user-friendliness. Finally, in the next decade or so, magnetic resonance imaging of other nuclei, such as fluorine and carbon, might become a reality in clinics, which would allow for metabolic and targeted molecular imaging with excellent sensitivity and specificity.
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