Alfvén Waves in the Interplanetary Medium
<p>A study of the wave properties of the microscale fluctuations (scale lengths of .01 a.u. and less) in the interplanetary medium is presented using plasma and magnetic field data from Mariner V (Venus 1967). The reduction procedure for the magnetic field data is summarized, and descripti...
| Summary: | <p>A study of the wave properties of the microscale fluctuations
(scale lengths of .01 a.u. and less) in the interplanetary medium is
presented using plasma and magnetic field data from Mariner V
(Venus 1967). The reduction procedure for the magnetic field data
is summarized, and descriptions are given of the MIT plasma data
and the merged plasma/field data tapes used in the analysis.</p>
<p>Observationally, it is found that large amplitude, nonsinusoidal
Alfvén waves propagating outward from the sun with a
broad wavelength range from 10<sup>3</sup> to 5 x 10<sup>6</sup>km dominate the
microscale structure at least 50% of the time. The waves frequently have
an energy density comparable both to the unperturbed magnetic
field energy density and to the thermal energy density. The purest
examples of the Alfvén waves are found in high velocity solar wind
streams and on their trailing edges. The largest amplitude waves
occur in the compression regions at the leading edges of high
velocity streams where the velocity increases rapidly with time. In
addition to being transverse to the average magnetic field direction,
e<sub>~B</sub>, the Alfvénic fluctuations generally exhibit a 10% partial
polarization in the e<sub>~B</sub>xe<sub>~R</sub> direction, where e<sub>~R</sub> is a unit vector radially away from the sun. Presumably magnetoacoustic wave modes occur, but
they have not been identified, and, if present, have a small average
power of the order of 10% or less of that in the Alfvén mode.</p>
<p>These observations are organized on the basis of a model of
the solar wind velocity structure. Most of the Alfvén waves in the
interplanetary medium seem likely to be the undamped remnants of
waves generated at or near the sun. The high level of wave activity
in high velocity, high temperature streams can be interpreted as
evidence for the extensive heating of these streams by wave damping
near the sun. The highest level of Alfvénic wave activity in the
compression regions at the leading edges of high velocity streams may
be due either to the amplification of ambient Alfvén waves in high
velocity streams as they are swept into the compression regions or
to the fresh generation of waves in these regions by the stream-stream
collisions. The observed absence of the magnetoacoustic
modes is evidence for their strong damping. The e<sub>~B</sub>xe<sub>~R</sub> anisotropy
is viewed as due to the partial conversion of the Alfvén waves to
the damped magnetoacoustic modes as they convected away from
the sun; this process continually transfers energy from the microscale
field fluctuations to the thermalized solar wind plasma.</p>
<p>The detailed behavior of the Alfvén waves and their effects
on the dynamics of the expanding solar corona as they propagate and
are convected out into interplanetary space is investigated in a
simplified one fluid polytrope model of the solar wind. It is found that
the inclusion of energy fluxes due to Alfvén waves at the base of the
corona can result in significant changes in the large streaming
properties of the solar wind.</p> |
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