Solar wind entry at low latitudes
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When Earth’s magnetic field and the interplanetary magnetic field are
aligned, for example in a northward orientation as indicated by the
white arrow in this graphic, Kelvin–Helmholtz waves are generated at low
(equatorial) latitudes.
Credits: AOES Medialab
ESA’s quartet of satellites studying Earth’s magnetosphere, Cluster, has
discovered that our protective magnetic bubble lets the solar wind in
under a wider range of conditions than previously believed.
Earth’s magnetic field is our planet’s first line of defence against the bombardment of the solar wind. This stream of plasma is launched by the Sun and travels across the Solar System, carrying its own magnetic field with it.
Earth’s magnetic field is our planet’s first line of defence against the bombardment of the solar wind. This stream of plasma is launched by the Sun and travels across the Solar System, carrying its own magnetic field with it.
Depending on how the solar wind’s interplanetary magnetic field – IMF –
is aligned with Earth’s magnetic field, different phenomena can arise in
Earth’s immediate environment.
One well-known process is magnetic reconnection, where magnetic field
lines pointing in opposite directions spontaneously break and reconnect
with other nearby field lines. This redirects their plasma load into the
magnetosphere, opening the door to the solar wind and allowing it to
reach Earth.
Under certain circumstances this can drive ‘space weather’, generating
spectacular aurorae, interrupting GPS signals and affecting terrestrial
power systems.
Solar wind entry at high latitudes
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When the interplanetary magnetic field, indicated by the white arrow, is
oriented westward (dawnward) or in the opposite, eastward (duskward)
direction, magnetopause boundary layers at higher latitude become most
subject to Kelvin–Helmholtz instabilities.
Credits: AOES Medialab
In 2006, Cluster made the surprising discovery that huge, 40 000 km
swirls of plasma along the boundary of the magnetosphere – the
magnetopause – could allow the solar wind to enter, even when Earth’s
magnetic field and the IMF are aligned.
These swirls were found at low, equatorial latitudes, where the magnetic fields were most closely aligned.
These giant vortices are driven by a process known as the
Kelvin–Helmholtz (KH) effect, which can occur anywhere in nature when
two adjacent flows slip past each other at different speeds.
Examples include waves whipped up by wind sliding across the surface of the ocean, or in atmospheric clouds.
Analysis of Cluster data has now found that KH waves can also occur at a
wider range of magnetopause locations and when the IMF is arranged in a
number of other configurations, providing a mechanism for the
continuous transport of the solar wind into Earth’s magnetosphere.
“We found that when the interplanetary magnetic field is westward or
eastward, magnetopause boundary layers at higher latitude become most
subject to KH instabilities, regions quite distant from previous
observations of these waves,” says Kyoung-Joo Hwang of NASA’s Goddard
Space Flight Center and lead author of the paper published in the Journal of Geophysical Research.
“In fact, it’s very hard to imagine a situation where solar wind plasma
could not leak into the magnetosphere, since it is not a perfect
magnetic bubble.”
The findings confirm theoretical predictions and are reproduced by simulations presented by the authors of the new study.
“The solar wind can enter the magnetosphere at different locations and
under different magnetic field conditions that we hadn’t known about
before,” says co-author Melvyn Goldstein, also from Goddard Space Flight
Center.
“That suggests there is a ‘sieve-like’ property of the magnetopause in
allowing the solar wind to continuously flow into the magnetosphere.”
The KH effect is also seen in the magnetospheres of Mercury and Saturn,
and the new results suggest that it may provide a possible continuous
entry mechanism of solar wind into those planetary magnetospheres, too.
“Cluster’s observations of these boundary waves have provided a great
advance on our understanding of solar wind – magnetosphere interactions,
which are at the heart of space weather research,” says Matt Taylor,
ESA’s Cluster project scientist.
“In this case, the relatively small separation of the four Cluster
satellites as they passed through the high-latitude dayside magnetopause
provided a microscopic look at the processes ripping open the
magnetopause and allowing particles from the Sun direct entry into the
atmosphere.”
Notes for Editors
ESA
Notes for Editors
ESA
Guillermo Gonzalo Sánchez Achutegui
ayabaca@gmail.com
ayabaca@hotmail.com
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