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Mössbauer Spectroscopy in Materials Science

  • Marcel Miglierini
  • Dimitris Petridis

Part of the NATO Science Series book series (ASHT, volume 66)

Table of contents

  1. Front Matter
    Pages i-x
  2. Chemistry, Mineralogy and Metallurgy

    1. Front Matter
      Pages 1-1
    2. F. J. Berry, C. Greaves, Ö. Helgason, K. Jónsson, J. McManus, S. J. Skinner
      Pages 1-12
    3. Ö. Helgason, B. Johannesson, B. Purser, F. Berry
      Pages 13-24
    4. G. Dénès, M. C. Madamba, A. Muntasar, A. Peroutka, K. Tam, Z. Zhu
      Pages 25-38
    5. Abdualhafeed Muntasar, Georges Dénès
      Pages 39-48
    6. Ernst-Georg Caspary, Tomáš Grygar
      Pages 57-62
    7. Kiyoshi Nomura
      Pages 63-78
    8. K. Bharuth-Ram, D. Naidoo, G. Klingelhöfer
      Pages 79-86
    9. U. D. Wdowik, K. Ruebenbauer
      Pages 87-96
    10. S. M. Dubiel, J. Cieślak, B. Sepiol
      Pages 107-118
  3. Artificially Structured Materials

    1. Front Matter
      Pages 131-131
    2. G. Le Caër, T. Ziller, P. Delcroix, J. P. Morniroli
      Pages 131-142
    3. L. Takacs, Vijayendra K. Garg
      Pages 143-150
    4. G. A. Dorofeev, G. N. Konygin, E. P. Yelsukov, I. V. Povstugar, A. N. Streletskii, P. Yu. Butyagin et al.
      Pages 151-160
    5. Peter Schaaf, Felix Landry
      Pages 161-172
    6. Y. Jirásková, O. Schneeweiss, V. Peřina, C. Blawert, B. L. Mordike
      Pages 173-182
    7. S. Havlíček, Y. Jirásková, O. Schneeweiss
      Pages 183-188
    8. G. Principi, A. Gupta
      Pages 189-202
    9. E. Kuzmann, M. EL-Sharif, C. U. Chisholm, G. Principi, C. Tosello, K. Havancsák et al.
      Pages 203-214
    10. A. L. Kholmetskii, V. V. Uglov, V. V. Khodasevich, V. M. Anischik, V. V. Ponaryadov, M. Mashlan
      Pages 215-226
  4. Nanosized Materials and Quasicrystals

    1. Front Matter
      Pages 227-227
    2. A. Simopoulos
      Pages 227-242
    3. Jean-Marc Grenèche, Marcel Miglierini
      Pages 243-256
    4. Marcel Miglierini, Jean-Marc Grenèche
      Pages 257-272
    5. J. Sitek, J. Degmová
      Pages 273-282
    6. E. P. Yelsukov, E. V. Voronina, G. N. Konygin, S. K. Godovikov, V. M. Fomin
      Pages 283-290
    7. K. Lázár, L. F. Kiss, S. Pronier, G. Onyestyák, H. K. Beyer
      Pages 291-298
  5. Experimental Techniques and Data Processing

    1. Front Matter
      Pages 307-307
    2. D. L. Nagy, L. Bottyán, L. Deák, J. Dekoster, G. Langouche, V. G. Semenov et al.
      Pages 323-336
    3. O. Schneeweiss, S. Havlíček, T. Žák
      Pages 337-348
    4. Moshe P. Pasternak, R. Dean Taylor
      Pages 349-358
    5. Paulo A. de Souza Jr., Vijayendra K. Garg
      Pages 359-372
    6. G. Pedrazzi, S. Z. Cai, I. Ortalli
      Pages 373-384
    7. T. Žák
      Pages 385-390
    8. M. Mashlan, D. Jancik, A. L. Kholmetskii
      Pages 391-398
    9. M. Mashlan, D. Jancik, D. Zak, F. Dufka, V. Snasel, A. L. Kholmetskii
      Pages 399-406
    10. M. Kwater, K. Ruebenbauer, U. D. Wdowik
      Pages 407-412
    11. G. Klingelhöfer
      Pages 413-426
  6. Back Matter
    Pages 427-432

About this book

Introduction

Material science is one of the most evolving fields of human activities. Invention and consequent introduction of new materials for practical and/or technological purposes requires as complete knowledge of the physical, chemical, and structural properties as possible to ensure proper and optimal usage of their new features. In order to understand the macroscopic behaviour, one has to search for their origin on a microscopic level. A good deal of microscopic information can be obtained through hyperfine interactions. Mossbauer spectroscopy offers a unique possibility for hyperfine interaction studies via probing the nearest order of resonant atoms. Materials which contain the respective isotope as one of the constituent elements (e.g., iron, tin, ... ) but also those which even do not contain them can be investigated. In the latter case, the probe atoms are incorporated into the material of interest in minor quantities (ca. 0.1 at. %) to act as probes on a nuclear level. This Workshop has covered the most evolving topics in the field of Mossbauer spectroscopy applied to materials science. During four working days, SO participants from 19 countries discussed the following areas: Chemisliy, Mineralogy and Metallurgy, Artificia/~y Structured Materials, Nanosized Materials and Quasicrvstals. and Experimental Techniques and Data Processing. A total of 42 contributions (30 keynote talks) reviewed the current state of art of the method, its applications for technical purposes, as well as trends and perspectives. A total of 39 papers are included in the present volume. Applications in Chemisfr\'.

Keywords

alloy atom crystal experiment iron kinetics material materials science metallurgy metals mineralogy Mössbauer spectroscopy nanoparticle spectroscopy Transit

Editors and affiliations

  • Marcel Miglierini
    • 1
  • Dimitris Petridis
    • 2
  1. 1.Department of Nuclear Physics and TechnologySlovak University of TechnologyBratislavaSlovakia
  2. 2.Institute of Materials ScienceNational Center for Scientific Research ‘Demokritos”AthensGreece

Bibliographic information

  • DOI https://doi.org/10.1007/978-94-011-4548-0
  • Copyright Information Kluwer Academic Publishers 1999
  • Publisher Name Springer, Dordrecht
  • eBook Packages Springer Book Archive
  • Print ISBN 978-0-7923-5641-7
  • Online ISBN 978-94-011-4548-0
  • Series Print ISSN 1388-6576
  • Buy this book on publisher's site
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