Everything about Corona totally explained
A
corona is a type of
plasma "
atmosphere" of the
Sun or other celestial body, extending millions of
kilometres into space, most easily seen during a total
solar eclipse, but also observable in a
coronagraph. The
Latin root of the word
corona means
crown.
The high temperature of the corona gives it unusual
spectral features, which led some to suggest, in the 19th century, that it contained a previously unknown element, "
coronium". These spectral features have since been traced to highly ionized Iron (Fe(XIV)) which indicates a plasma temperature in excess of 10
6 kelvin.
The corona is divided into three parts. The K-corona (K for continuum) interfaces directly with the
chromosphere and is created by sunlight scattering off
electrons. The E-corona (E for emission) contains abundant calcium and iron. The F-corona (F for
Fraunhofer) is created by sunlight bouncing off dust particles.
Physical features
The Sun's corona is much hotter (by a factor of nearly 200) than the visible surface of the Sun: the
photosphere's average
temperature is 5800
kelvin compared to the corona's one to three million kelvin. The corona is 10
−12 as dense as the photosphere, however, and so produces about one-millionth as much visible light. The corona is separated from the photosphere by the relatively shallow
chromosphere. The exact mechanism by which the corona is heated is still the subject of some debate, but likely possibilities include induction by the Sun's
magnetic field and
sonic pressure waves from below (the latter being less probable now that coronae are known to be present in early-type, highly magnetic
stars). The outer edges of the Sun's corona are constantly being transported away due to open magnetic flux generating the
solar wind.
The Corona isn't always evenly distributed across the surface of the sun. During periods of quiet, the corona is more or less confined to the
equatorial regions, with
coronal holes covering the
polar regions. However during the Sun's active periods, the corona is evenly distributed over the equatorial and polar regions, though it's most prominent in areas with
sunspot activity. The
solar cycle spans approximately 11 years, from
solar minimum to
solar maximum, where the solar magnetic field is continually wound up (due to a
differential rotation at the solar
equator; the equator rotates quicker than the poles). Sunspot activity will be more pronounced at solar maximum where the
magnetic field is twisted to a maximum. Associated with sunspots are
coronal loops, loops of
magnetic flux, upwelling from the solar interior. The magnetic flux pushes the hotter
photosphere aside, exposing the cooler plasma below, thus creating the dark (when compared to the solar disk) spots.
Coronal Loops
Coronal loops are the basic structures of the magnetic solar corona. These loops are the closed-magnetic flux cousins of the open-magnetic flux that can be found in
coronal hole (polar) regions and the
solar wind. Loops of magnetic flux well up from the solar body and fill with hot solar plasma. Due to the heightened magnetic activity in these coronal loop regions, coronal loops can often be the precursor to
solar flares and
Coronal Mass Ejections (CMEs). Solar plasma feeding these structures are heated from under 6000K to well over 1×10
6K from the photosphere, through the transition region, and into the corona. Often, the solar plasma will fill these loops from one foot point and drain from the other (
siphon flow due to a pressure difference, or asymmetric flow due to some other driver). This is known as chromospheric
evaporation and chromosperic
condensation respectively. There may also be
symmetric flow from both loop foot points, causing a buildup of mass in the loop structure. The plasma may cool in this region creating dark
filaments in the solar disk or
prominences off the
limb. Coronal loops may have lifetimes in the order of seconds (in the case of flare events), minutes, hours or days. Usually coronal loops lasting for long periods of time are known as
steady state or
quiescent coronal loops, where there's a balance in loop energy sources and sinks (
example
).
Coronal loops have become very important when trying to understand the current
coronal heating problem. Coronal loops are highly radiating sources of plasma and therefore easy to observe by instruments such as
TRACE, they're highly observable
laboratories to study phenomena such as solar oscillations, wave activity and
nanoflares. However, it remains difficult to find a solution to the coronal heating problem as these structures are being observed remotely, where many ambiguities are present (for example radiation contributions along the
LOS).
In-situ measurements are required before a definitive answer can be arrived at, but due to the high plasma temperatures in the corona,
in-situ measurements are impossible (at least for the time-being).
Transients
Generated by
solar flares or large
solar prominences,
"coronal transients" (also called
coronal mass ejections) are sometimes released. These are enormous loops of coronal material traveling outward from the Sun at over a million kilometers per hour, containing roughly 10 times the energy of the solar flare or prominence that triggered them. Some larger ejections can propel hundreds of millions of tons of material in to
space at roughly a million miles an hour.
Other stars
Stars other than the Sun have coronae, which can be detected using
X-ray telescopes. Some stellar coronae, particularly in young stars, are much more luminous than the Sun's.
Coronal heating problem
The
coronal heating problem in
solar physics relates to the question of why the temperature of the Sun's corona is millions of kelvin higher than that of the surface. The high temperatures require energy to be carried from the solar interior to the corona by non-thermal processes, because the
second law of thermodynamics prevents heat from flowing directly from the solar photosphere, or surface, at about 5800 kelvin, to the much hotter corona at about 1 to 3
MK (parts of the corona can even reach 10 MK). The amount of power required to heat the solar corona can easily be calculated. It is about 1 kilowatt for every square meter of surface area on the Sun, or 1/40000 of the amount of light energy that escapes the Sun.
This thin region of temperature increase from the chromosphere to the corona is known as the
transition region and can range from tens to hundreds of kilometers thick. An analogy
of this would be a light bulb heating the air surrounding it hotter than its glass surface.
The
second law of thermodynamics would be broken. So, what mechanism is heating
the tenuous coronal plasma to these temperatures?
Many coronal heating theories have been proposed, but two theories have remained as the
most likely candidates,
wave heating and
magnetic reconnection (or
nanoflares). Through most of the past 50 years, neither theory has been able to account for the extreme coronal temperatures. Most
solar physicists now believe that some combination of the two theories can probably explain coronal heating, although the details are not yet complete.
The
NASA mission
Solar Probe + is intended to approach the sun to a distance of approximately 9.5 solar radii in order to investigate coronal heating and the origin of the solar wind.
Competing heating mechanisms>
| Heating Models |
| Hydrodynamic |
Magnetic
|
- No magnetic field
- Slow rotating stars
| DC (reconnection) |
AC (waves)
|
|
| B-field stresses
Reconnection events
Flares
Uniform heating rates
|
Photospheric foot point shuffling
MHD wave propagation
High Alfvén wave flux
Non-uniform heating rates
|
| Not our Sun! |
Competing theories |
Wave heating theory
The
wave heating theory, proposed in 1949 by
Evry Schatzman, proposes that waves carry energy from the solar interior to the solar chromosphere and corona. The Sun is made of
plasma rather than ordinary gas, so it supports several types of waves analogous to
sound waves in air. The most important types of wave are
magneto-acoustic waves and
Alfvén waves. Magneto-acoustic waves are sound waves that have been modified by the presence of a magnetic field, and Alfvén waves are similar to
ULF radio waves that have been modified by interaction with
matter in the plasma. Both types of waves can be launched by the turbulence of
granulation and
super granulation at the solar photosphere, and both types of waves can carry energy for some distance through the solar atmosphere before turning into
shock waves that dissipate their energy as heat.
One problem with wave heating is delivery of the heat to the appropriate place. Magneto-acoustic waves can't carry sufficient energy upward through the chromosphere to the corona, both because of the low pressure present in the chromosphere and because they tend to be
reflected back to the photosphere. Alfvén waves can carry enough energy, but don't dissipate that energy rapidly enough once they enter the corona. Waves in plasmas are notoriously difficult to understand and describe analytically, but computer simulations, carried out by
Thomas Bogdan and colleagues in 2003, seem to show that Alfvén waves can transmute into other wave modes at the base of the corona, providing a pathway that can carry large amounts of energy from the photosphere into the corona and then dissipate it as heat.
Another problem with wave heating has been the complete absence, until the late 1990s, of any direct evidence of waves propagating through the solar corona. The first direct observation of waves propagating into and through the solar corona was made in 1997 with the
SOHO space-borne solar observatory, the first platform capable of observing the Sun in the
extreme ultraviolet for long periods of time with stable
photometry. Those were magneto-acoustic waves with a frequency of about 1
millihertz (mHz, corresponding to a 1,000 second wave period), that carry only about 10% of the energy required to heat the corona. Many observations exist of localized wave phenomena, such as Alfvén waves launched by solar flares, but those events are transient and can't explain the uniform coronal heat.
It isn't yet known exactly how much wave energy is available to heat the corona. Results published in 2004 using data from the
TRACE spacecraft seem to indicate that there are waves in the solar atmosphere at frequencies as high as 100 mHz (10 second period). Measurements of the temperature of different
ions in the solar wind with the
UVCS instrument aboard SOHO give strong indirect evidence that there are waves at frequencies as high as 200 Hz, well into the range of human hearing. These waves are very difficult to detect under normal circumstances, but evidence collected during solar eclipses by teams from
Williams College suggest the presences of such waves in the 1–10 Hz range.
Magnetic reconnection theory
The
Magnetic reconnection theory relies on the solar magnetic field to induce electric currents in the solar corona. The currents then collapse suddenly, releasing energy as heat and wave energy in the corona. This process is called "reconnection" because of the peculiar way that magnetic fields behave in a plasma (or any electrically conductive fluid such as
mercury or
seawater). In a plasma,
magnetic field lines are normally tied to individual pieces of matter, so that the
topology of the magnetic field remains the same: if a particular north and south
magnetic pole are connected by a single field line, then even if the plasma is stirred or if the magnets are moved around, that field line will continue to connect those particular poles. The connection is maintained by electric currents that are induced in the plasma. Under certain conditions, the electric currents can collapse, allowing the magnetic field to "reconnect" to other magnetic poles and release heat and wave energy in the process.
Magnetic reconnection is hypothesized to be the mechanism behind solar flares, the largest explosions in our solar system. Furthermore, the surface of Sun is covered with million of small magnetized regions 50–1,000 km across. These small magnetic poles are buffeted and churned by the constant granulation. The magnetic field in the solar corona must undergo nearly constant reconnection to match the motion of this "magnetic carpet", so the energy released by the reconnection is a natural candidate for the coronal heat, perhaps as a series of "microflares" that individually provide very little energy but together account for the required energy.
The idea that micro flares might heat the corona was put forward by
Eugene Parker in the 1980s but is still controversial. In particular,
ultraviolet telescopes such as TRACE and SOHO/EIT can observe individual micro-flares as small brightenings in extreme ultraviolet light, but there seem to be too few of these small events to account for the energy released into the corona. The additional energy not accounted for could be made up by wave energy, or by gradual magnetic reconnection that releases energy more smoothly than micro-flares and therefore doesn't appear well in the TRACE data. Variations on the micro flare hypothesis use other mechanisms to stress the magnetic field or to release the energy, and are a subject of active research in 2005.
Further Information
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