Journal ArticleDOI
Interplanetary ions during an energetic storm particle event - The distribution function from solar wind thermal energies to 1.6 MeV
J. T. Gosling,J. R. Asbridge,S. J. Bame,W. C. Feldman,R. D. Zwickl,G. Paschmann,N. Sckopke,R. J. Hynds +7 more
TLDR
In this paper, an ion velocity distribution function f(v) extending from solar wind energies (-1 keV) to 1.6 MeV during the postshock phase of an energetic storm particle (ESP) event was obtained.Abstract:
Data from the Los Alamos Scientific Laboratory/Max-Planck-Institut fast plasma experiment on Isee 2 have been combined with data from the European Space Agency/Imperial College/Space Research Laboratory low-energy proton experiment on Isee 3 to obtain for the first time an ion velocity distribution function f(v) extending from solar wind energies (-1 keV) to 1.6 MeV during the postshock phase of an energetic storm particle (ESP) event. This study reveals that f(v) of the ESP population is roughly isotropic in the solar wind frame from solar wind thermal energies out to 1.6 MeV. Emerging smoothly out of the solar wind thermal distribution, the ESP f(v) initially falls with increasing energy as E/sup -2.4/ in the solar wind frame. Above about 40 keV no single power law exponent adequately describes the energy dependence of f(v) in the solar wind frame. Above approx.200 keV in both the spacecraft frame and the solar wind frame, f(v) can be described by an exponential in speed (f(v)proportionale/sup -v/v//sub o/) with v/sub o/ = 1.05 x 10/sup 8/ cm s /sup -1/. The ESP event studied (August 27, 1978) was superposed upon a more energetic particle event which was predominantly field-aligned and which was probably of solar origin.more » Our observations suggest that the ESP population is accelerated directly out of the solar wind thermal population or its quiescent suprathermal tail by a stochastic process associated with the shock wave disturbance. The acceleration mechanism is sufficiently efficient that approx.1% of the solar wind population is accelerated to suprathermal energies. These suprathermal particles have an energy density of approx.290 eV cm/sup -3/.« lessread more
Citations
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Particle acceleration at astrophysical shocks: A theory of cosmic ray origin
TL;DR: In this article, the theory of first order Fermi acceleration at collisionless astrophysical shock fronts is reviewed and it is argued that the wave amplitude is probably non-linear within sufficiently strong astrophysical shocks.
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The solar flare myth
TL;DR: In this paper, the authors outline a different paradigm of cause and effect that removes solar flares from their central position in the chain of events leading from the Sun to near-Earth space.
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Particle Acceleration at the Sun and in the Heliosphere
TL;DR: In this article, the authors compare different populations of the sources and learn more about the sources, and about the physics of acceleration and transport, than we can possibly learn from one source alone.
Journal ArticleDOI
The modified plasma dispersion function
Danny Summers,Richard M. Thorne +1 more
TL;DR: The modified plasma dispersion function (MPDF) as mentioned in this paper is based on the generalized Lorentzian (kappa) particle distribution function, and a comprehensive set of graphs of the real and imaginary parts of the MPDF is presented.
Journal ArticleDOI
The plasma physics of shock acceleration
Frank C. Jones,Donald C. Ellison +1 more
TL;DR: In this paper, a review of the history and theory of particle acceleration is presented, paying particular attention to theories of parallel shocks which include the backreaction of accelerated particles on the shock structure, and the work that computer simulations, both plasma and Monte Carlo, are playing in revealing how thermal ions interact with shocks.
References
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Journal ArticleDOI
Observations of interaction regions and corotating shocks between one and five AU: Pioneers 10 and 11
Edward J. Smith,John H. Wolfe +1 more
TL;DR: In this article, the interaction regions between adjacent solar-wind streams have been identified between 1 and 5 AU by Pioneer 10 and 11 magnetic-field and plasma measurements, and a relatively large fraction of the interactions are accompanied by either forward shocks, reverse shocks, or shock pairs.
Observations of interaction regions and corotating shocks between one and five AU - Pioneers 10 and 11. [solar wind streams]
E. J. Smith,J. H. Wolfe +1 more
TL;DR: In this article, a relatively large fraction of the interaction regions have been found to be accompanied by either forward shocks, reverse shocks, or shock pairs, consistent with previous theoretical proposals that the interaction between adjacent solar wind streams leads to the development of corotating interplanetary shocks.
Journal ArticleDOI
The speeds of coronal mass ejection events
TL;DR: In this article, it was shown that the fastest mass ejection events are almost always associated with flares and with metric wavelength type II and IV radio bursts, which explains why major shock wave disturbances in the solar wind at 1 AU are most often associated with these forms of solar activity rather than with eruptive prominences.
Journal ArticleDOI
Evidence for interplanetary acceleration of nucleons in corotating interaction regions
Cris W. Barnes,J. A. Simpson +1 more
TL;DR: In this article, a correlation was found between the positions of double peaks in recurring proton intensity increases and the leading and trailing edges of recurring regions of fast solar wind streams and enhanced magnetic field.