The stellar atmosphere is divided into several regions of distinct character:
The
photosphere, which is the atmosphere's lowest and coolest layer, is normally its only visible part.[1]Light escaping from the surface of the star stems from this region and passes through the higher layers. The
Sun's photosphere has a
temperature in the 5,770–5,780
K (5,500–5,510
°C; 9,930–9,940
°F) range.[2][3]Starspots, cool regions of disrupted
magnetic field, lie in the photosphere.[3]
Above the photosphere lies the
chromosphere. This part of the atmosphere first cools down and then starts to heat up to about 10 times the temperature of the photosphere.
Above the chromosphere lies the
transition region, where the temperature increases rapidly on a distance of only around 100 km (62 mi).[4]
Additionally, many stars have a molecular layer (MOLsphere) above the photosphere and just beyond or even within the chromosphere.[5] The molecular layer is cool enough to contain molecules rather than plasma, and may consist of such components as carbon monoxide, water vapor, silicon monoxide, and titanium oxide.
The outermost part of the stellar atmosphere, or upper stellar atmosphere, is the
corona, a tenuous
plasma which has a temperature above one million Kelvin.[6] While all stars on the
main sequence feature transition regions and coronae, not all
evolved stars do so. It seems that only some
giants, and very few
supergiants, possess coronae.
An unresolved problem in stellar
astrophysics is how the corona can be heated to such high temperatures. The answer is believed to lie in
magnetic fields, but the exact mechanism remains unclear.[7]
The
astrosphere, which is in the case of the Sun the
heliosphere,[8] can be in a broader understanding considered the furthest part of a stellar atmosphere,[9][10] before
interstellar space begins at the
heliopause. The astrosphere is not to be confused with the
Solar System and its outermost region the
Oort cloud, which extends much further than the astrosphere, therefore far into interstellar space.
During a total
solar eclipse, the photosphere of the Sun is
obscured, revealing its atmosphere's other layers.[1] Observed during eclipse, the Sun's chromosphere appears (briefly) as a thin pinkish
arc,[11] and its corona is seen as a tufted
halo. The same phenomenon in
eclipsing binaries can make the chromosphere of giant stars visible.[12]
See also
Cecilia Payne-Gaposchkin, who first proposed the presently-accepted composition of stellar atmospheres
^
ab""Beyond the Blue Horizon" – A Total Solar Eclipse Chase". 1999-08-05. Retrieved 2010-05-21. On ordinary days, the corona is hidden by the blue sky, since it is about a million times fainter than the layer of the sun we see shining every day, the photosphere.
^
abLang, K. R. (September 2006). "5.1 MAGNETIC FIELDS IN THE VISIBLE PHOTOSPHERE". Sun, earth, and sky (2nd ed.). Springer. p. 81.
ISBN978-0-387-30456-4. this opaque layer is the photosphere, the level of the Sun from which we get our light and heat
^Mariska, J. T. (1992). The solar transition region. Cambridge University Press. p. 60.
ISBN978-0-521-38261-8. 100 km suggested by average models
^"The Sun's Corona – Introduction".
NASA. Retrieved 2010-05-21. Now most scientists believe that the heating of the corona is linked to the interaction of the magnetic field lines.
^
Lewis, J.S. (2004-02-23). Physics and chemistry of the solar system (Second ed.). Elsevier Academic Press. p. 87.
ISBN978-0-12-446744-6. The dominant color is influenced by the
Balmer radiation of atomic hydrogen