Giant resonance phenomena in intermediate-energy nuclear reactions
Read Online
Share

Giant resonance phenomena in intermediate-energy nuclear reactions by F. Cannata

  • 563 Want to read
  • ·
  • 73 Currently reading

Published by Springer-Verlag in Berlin, New York .
Written in English

Subjects:

  • Nuclear magnetic resonance, Giant.,
  • Nuclear reactions.

Book details:

Edition Notes

Includes bibliographical references and index.

StatementF. Cannata, H. Überall.
SeriesSpringer tracts in modern physics ;, 89
ContributionsÜberall, Herbert, 1931- joint author.
Classifications
LC ClassificationsQC1 .S797 vol. 89, QC762 .S797 vol. 89
The Physical Object
Paginationviii, 112 p. :
Number of Pages112
ID Numbers
Open LibraryOL4100514M
ISBN 100387101055
LC Control Number80014938

Download Giant resonance phenomena in intermediate-energy nuclear reactions

PDF EPUB FB2 MOBI RTF

Giant resonance phenomena in intermediate-energy nuclear reactions. Berlin ; New York: Springer-Verlag, (OCoLC) Material Type: Internet resource: Document Type: Book, Internet Resource: All Authors / Contributors: F Cannata; Herbert Überall. The interaction between the nucleus and an external probe --Dipole and multiple giant resonances in electron scattering --Giant resonances in muon capture --Resonance excitation by neutrinos --Photoproduction and radiative capture of pions --Higher-multiple giant resonance excitation by hadrons. Series Title: Springer tracts in modern physics, Giant resonances are collective excitations of the atomic nucleus, a typical quantum many-body system. The study of these fundamental modes has in many respects contributed to our understanding of the bulk behavior of the nucleus and of the dynamics of non-equilibrium excitations. Although the phenomenon of giant resonances has been known for more than 50 years, a large amount of information has been . Giant resonances 1 are broad, resonance-like structures in excitation functions with large cross sections, excited by incident γ rays as well as in inelastic particle reactions such as. Their unusually large width is a consequence of the high excitation energy with many open decay channels and .

Description. Giant resonances are collective excitations of the atomic nucleus, a typical quantum many-body system. The study of these fundamental modes has in many respects contributed to our understanding of the bulk behavior of the nucleus and of the dynamics of non-equilibrium excitations.   Capture Rate Giant Resonance Single Particle Spectrum Dipole Excitation Muon Capture These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves. Cite this chapter as: Cannata F., Überall H. () Dipole and multiple giant resonances in electron scattering. In: Giant Resonance Phenomena in Intermediate-Energy Nuclear Reactions. Kupte si knihu Giant Resonance Phenomena in Intermediate Energy Nuclear Reactions: Cannata, Francesco;Uberall, H.: za nejlepší cenu se slevou. Podívejte se i na další z miliónů zahraničních knih v naší nabídce. Zasíláme rychle a levně po ČR.

Genre/Form: Electronic books: Additional Physical Format: Print version: Cannata, F., Giant resonance phenomena in intermediate-energy nuclear reactions. Abstract Citations (3) References Co-Reads NASA/ADS. Giant Resonance Phenomena in Intermediate-Energy Nuclear Reactions Cannata, Francesco; Überall, Herbert; Abstract. Publication: Springer Tracts in Modern Physics. Pub Date: DOI. 1.D Nuclear Physics 28 () ; North-Holland Publishing Co., Amsterdam 2.E Not to be reproduced by photoprint or microfilm without written permission from the publisher OPTICAL GIANT RESONANCES IN NUCLEAR REACTIONS KARL WILDERMUTH Florida State University and the Oak Ridge National Laboratory and ROBERT L. CAROVILLANO t Boston College Received 29 May . This thesis reports on investigations of a specific collective mode of nuclear vibration, the isoscalar giant monopole resonance (ISGMR), the nuclear "breathing mode", the energy of which is directly related to a fundamental property of nuclei—the nuclear incompressibility. The alpha inelastic.