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1. Introduction and overview<br> 2. Coronal magnetic loop as an equivalent electric circuit<br> 2.1. Physical model of an isolated loop<br> 2.2. The formation of magnetic tubes by photosphere convection<br> 2.3. The structure of the coronal part of a flux tube<br> 2.4. Diagnostics of electric currents<br> 2.5. Equivalent electric circuit<br> 2.6. Inductive interaction of magnetic loops<br> 2.7. Waves of electric current in arcades of coronal magnetic loops<br> 2.8. Magnetic loops above spots<br> <br> 3. Resonators for MHD oscillations in stellar coronae<br> 3.1. Eigen-modes of coronal loops: Plasma cylinder approach and the dispersion equation<br> 3.2. MHD-resonator at ~ 1RO in the solar corona<br> 3.3. Excitation mechanisms for loop oscillations<br> <br> 4. Propagating MHD waves in coronal plasma waveguides<br> 4.1 MHD waves in vertical coronal magnetic flux tubes<br> 4.2 Propagating waves in coronal loops<br> 4.3 Waves in coronal jets<br> 4.4 Evolution of short-wavelength fast magnetoacoustic waves<br> 4.5 Alfven wave phase mixing<br> 5. Prominence seismology <br> 5.1. Prominence models<br> 5.2, Prominence oscillations<br> 5.3. The heating effect<br> 5.4. Non-linear oscillations. Dynamic modes<br> 5.5. Flare processes in prominences.<br> 5.6. Stellar and interstellar prominences<br> <br> 6. The coronal loop as a magnetic mirror trap <br> 6.1. Particle distribution in a coronal loop<br> 6.1.1. Gyrosynchrotron emission from a flaring loop<br> 6.2. Kinetic instabilities in a loop<br> 6.2.1. Loop as Electron Cyclotron Maser <br> 6.2.2. Plasma mechanism of radio emission from coronal loops<br> 6.2.3. Instabilities of whistlers and small-scale Alfven waves<br> 6.3. Fine structure of the solar and stellar radio emission <br> <br> 7. Flaring events in stellar coronal loops <br> 7.1. Particle acceleration and explosive Joule heating in current-carrying loops <br> conductivity<br> 7.2. Kinematics of energetic particles in a loop and the consequent radiation<br> <br> 8. Stellar coronal seismology as a diagnostic tool for flare plasma<br> <br> 8.1. Modulation of flaring emission by MHD oscillations<br> 8.2. Global sausage mode and diagnostics of the solar event of the 12th of January, 2000<br> 8.3. Dissipative processes in coronal loop for MHD modes<br> 8.4. Diagnostics of flaring plasma parameters in solar and stellar flares<br> 8.5. Diagnostics of electric currents in stellar atmosphere <br> <br> 9. Heating mechanisms in stellar coronae <br> 9.1. Wave heating <br> 9.2. Ohmic dissipation of electric currents <br> 9.3. Heating by microflares<br> <br> 10. Loops and QPO in neutron stars and accretion discs <br> 10.1. Loops in accretion discs, heating of disc corona<br> 10.2. The origin of fast QPOs from magnetars and diagnostics of magnetar corona<br> <br> 11. Conclusion<br>

Alexander V. Stepanov is director of the Pulkovo Observatory, Russia, and elected member of the European Astronomical Society Council. 150 papers on various processes related to flares and the solar corona and how to measure and interpret their emissions prove his standing with the community.<br> <br> Valery V. Zaitsev is head of the Laboratory of Plasma Physics of the Atmospheres of the Sun and Planets at the Russian Academy of Sciences, and Founding Member of the European Astronomical Society.Various assignments have taken him to the European Southern Observatory and the Astrophys. Institute Potsdam, Germany, among others. <br> His research centers on solar and stellar flares, winds and radio emission, coronal structures and plasma kinetics. It is documented in over 200 publications.<br> <br> Valery M. Nakariakov is Professor at the University of Warwick, UK, Councilor of the Royal Astronomical Society and Vice President of the European Solar Physics Division of the European Physical Society. His research focuses on astrophysical and laboratory plasmas, on solar coronal physics and magnetohydrodynamic coronal seismology.<br>

<p><b>T</b>his concise and systematic account of the current state of this new branch of astrophysics presents the theoretical foundations of plasma astrophysics, magneto-hydrodynamics and coronal magnetic structures, taking into account the full range of available observation techniques – from radio to gamma.</p> <p>The book discusses stellar magnetic loops during flare energy releases, MHD waves and oscillations, plasma instabilities and heating and charged particle acceleration. Current trends and developments in MHD seismology of solar and stellar coronal plasma systems are also covered, while recent progress is presented in the observational study of quasiperiodic pulsations in solar and stellar flares with radio, optical, X and gamma rays. In addition, the authors investigate plasma instabilities and the origin of coherent radio emission from stellar loops, paying special attention to their fine structure.</p> <p><b>From the contents:</b></p> <ul> <li>Introduction and overview</li> <li>Coronal magnetic loop as an equivalent electric circuit</li> <li>Resonators for MHD oscillations in stellar coronae</li> <li>Propagating MHD waves in coronal plasma waveguides</li> <li>Prominence seismology</li> <li>The coronal loop as a magnetic mirror trap</li> <li>Flaring events in stellar coronal loops</li> <li>Stellar coronal seismology as a diagnostic tool for flare plasma</li> <li>Heating mechanisms in stellar coronae</li> <li>Loops and QPOs in accretion disks and neutron stars</li> <li>Conclusion</li> </ul>

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