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The M?ossbauer effect /

"Version: 20231101"--Title page verso.Includes bibliographical references.1. The history of resonance fluorescence -- 1.1. Introduction -- 1.2. Atomic resonance fluorescence -- 1.3. The Heisenberg linewidth and recoil energy -- 1.4. The early history of nuclear resonance fluorescence -- 1.5. Problems2. The M?ossbauer effect -- 2.1. Introduction -- 2.2. Discovery of the M?ossbauer effect -- 2.3. More about the M?ossbauer effect -- 2.4. Choice of a M?ossbauer transition -- 2.5. Properties of 57Fe -- 2.6. Properties of 119Sn -- 2.7. Other common M?ossbauer nuclides -- 2.8. Problems3. Properties of the nucleus -- 3.1. Introduction -- 3.2. Nuclear quantum numbers -- 3.3. Electromagnetic multipole moments of the nucleus4. Hyperfine interactions--part I : the electric monopole interaction and the chemical isomer shift -- 4.1. Introduction -- 4.2. The electric monopole interaction -- 4.3. The chemical isomer shift -- 4.4. The second order Doppler shift5. Hyperfine interactions--part II : the electric quadrupole interaction -- 5.1. Introduction -- 5.2. The electric quadrupole interaction -- 5.3. Quadrupole splitting of M?ossbauer spectra -- 5.4. Intensity of absorption lines6. Magnetic properties of materials -- 6.1. Introduction -- 6.2. Paramagnetic materials -- 6.3. Ferromagnetic materials and mean field theory -- 6.4. Antiferromagnetic materials -- 6.5. Ferrimagnetic materials7. Hyperfine interactions--part III : the magnetic dipole interaction and the nuclear Zeeman effect -- 7.1. Introduction -- 7.2. The magnetic dipole interaction -- 7.3. Zeeman splitting of M?ossbauer spectra -- 7.4. Intensity of absorption lines -- 7.5. Combined hyperfine interactions -- 7.6. Problems8. Experimental aspects of M?ossbauer spectroscopy -- 8.1. Introduction -- 8.2. M?ossbauer spectroscopy drive system -- 8.3. Gamma-ray spectroscopy -- 8.4. Data accumulation -- 8.5. Velocity calibration -- 8.6. Data analysis -- 8.7. Temperature control -- 8.8. Transmission and backscatter geometries -- 8.9. Internal conversion electron M?ossbauer spectroscopy9. Applications of M?ossbauer spectroscopy to physics, chemistry and materials science -- 9.1. Introduction -- 9.2. General relativity -- 9.3. Magnetic ordering studies -- 9.4. Crystallographic structure studies -- 9.5. Hyperfine field distributions -- 9.6. Impurity studies -- 9.7. Surface studies -- 9.8. Studies of battery materials10. Applications of M?ossbauer spectroscopy to other fields -- 10.1. Introduction -- 10.2. Mineralogical studies -- 10.3. Studies of natural glasses -- 10.4. Investigations of extraterrestrial materials -- 10.5. Archaeological studies -- 10.6. Biological studies -- 10.7. Counterfeit currency detection11. Ion implantation and synchrotron radiation-based M?ossbauer studies -- 11.1. Introduction -- 11.2. Ion implantation studies -- 11.3. Off-line M?ossbauer spectroscopy -- 11.4. On-line M?ossbauer spectroscopy -- 11.5. In-beam M?ossbauer spectroscopy -- 11.6. Fundamentals of synchrotron radiation -- 11.7. Synchrotron radiation-based M?ossbauer techniques -- 11.8. Time domain synchrotron M?ossbauer spectroscopy -- 11.9. Energy domain synchrotron M?ossbauer spectroscopy.In this updated and significantly expanded second edition of The M?ossbauer Effect, an introduction to the M?ossbauer effect is provided for the non-specialist with a general background in undergraduate physics. A wide variety of M?ossbauer applications are covered. These include general relativity, as well as the physical and chemical properties of materials. Applications in other fields including mineralogy, archaeology, space science, and biology are discussed. The book also contains descriptions of some more advanced M?ossbauer spectroscopic techniques, such as ion implantation and synchrotron radiation based M?ossbauer spectroscopy. This second edition includes a new chapter on experimental methods and updated and greatly expanded material on applications of the M?ossbauer effect.Science/engineering students and professionals who would like an introduction to M?ossbauer effect and its applications and who would like to understand its potential in diverse areas of research.Also available in print.Mode of access: World Wide Web.System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.Richard A. Dunlap is a Research Professor at Dalhousie University in Canada. He joined Dalhousie University in 1981 and became a full professor in 1990. He was the director of the Dalhousie University Institute for Research in Materials from 2009 to 2015. Having published more than 300 refereed research papers, his research interests include nuclear spectroscopies, magnetic materials, quasicrystals, critical phenomena and advanced batteries materials. He is the author of thirteen books, including seven with IOP ebooks.Title from PDF title page (viewed on January 4, 2024).

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Series Title
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Call Number
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Publisher
: .,
Collation
1 online resource (various pagings) :illustrations (some color).
Language
English
ISBN/ISSN
9780750360395
Classification
537.5/352
Content Type
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Media Type
-
Carrier Type
-
Edition
Second edition.
Subject(s)
SCIENCE / Physics / Atomic & Molecular.
Atomic & molecular physics.
M?ossbauer effect.
M?ossbauer spectroscopy.
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