Primality test: Difference between revisions

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{{About|gas ejected from the atmosphere of stars}}
Hello, I am Lida but you could call me anything you like.  For years I've been living in West Virginia and I do not intend on changing itDistributing production is my day job today. My husband doesn't like it the way in which I do but what I actually like doing is behaving and I'm going to be starting another thing in addition to it.<br><br>Here is my blog post; [http://20thstreetblockparty.com/2014/jordan-kurland-intro/ Jordan Kurland]
 
A '''stellar wind''' is a flow of neutral or charged gas ejected from the [[stellar atmosphere|upper atmosphere]] of a [[star]]It is distinguished from the [[bipolar outflow]]s characteristic of young stars by being less [[collimated]], although stellar winds are not generally spherically symmetric.
 
Different [[stellar classification|types]] of stars have different types of stellar winds.
 
Post-[[main sequence|main-sequence]] [[star]]s nearing the ends of their lives often eject large quantities of mass in massive (<math> \scriptstyle \dot{M} > 10^{-3}</math> solar masses per year), slow (v = 10&nbsp;km/s) winds.  These include [[red giant]]s and [[Red supergiants|supergiants]], and [[asymptotic giant branch]] stars.  These winds are likely to be driven by [[radiation pressure]] on [[Cosmic dust|dust]] condensing in the upper atmosphere of the stars.
 
Massive stars of [[stellar classification|types]] [[O star|O]] and [[B V star|B]] have stellar winds with lower mass loss rates (<math>\scriptstyle \dot{M} < 10^{-6}</math> solar masses per year) but very high velocities (v > 1–2000&nbsp;km/s). Such winds are driven by radiation pressure on the resonance absorption lines of heavy elements such as carbon and nitrogen.<ref>{{cite journal| bibcode=1975ApJ...195..157C| last= Castor| first=J.| coauthors=Abbott, D. C., &amp; [[Richard Klein (astronomer)|Klein, R. I.]]| title=Radiation-driven winds in Of stars| year=1975| journal=Astrophys. J.| volume=195| pages=157–174| doi=10.1086/153315}}</ref>  These high-energy stellar winds blow [[stellar wind bubble]]s.
 
[[G-type main-sequence star|G-type stars]] like the [[Earth|Earth's]] [[Sun]], have a wind driven by their hot, magnetized [[corona]]. The Sun's wind is called the [[solar wind]].  These winds consist mostly of high-energy [[electrons]] and [[proton]]s (about 1 [[electron volt|keV]]) that are able to escape the star's [[gravity]] because of the high [[temperature]] of the [[corona]].
 
Stellar winds from [[main sequence|main-sequence]] [[star]]s do not strongly influence the evolution of lower mass stars such as the Sun. However, for more massive stars such as O stars, the mass loss can result in a star shedding as much as 50% of its mass whilst on the main sequence: this clearly has a significant impact on the later stages of evolution. The influence can even be seen for intermediate mass stars, which will become [[white dwarf]]s at the ends of their lives rather than exploding as [[supernova]]e only because they lost enough mass in their winds.
 
==See also==
{{Portal|Space}}
* [[Solar wind]]
* [[Cosmic ray]]
 
==References==
<references/>
 
{{Star}}
 
{{DEFAULTSORT:Stellar Wind}}
[[Category:Stellar astronomy]]

Latest revision as of 17:50, 11 January 2015

Hello, I am Lida but you could call me anything you like. For years I've been living in West Virginia and I do not intend on changing it. Distributing production is my day job today. My husband doesn't like it the way in which I do but what I actually like doing is behaving and I'm going to be starting another thing in addition to it.

Here is my blog post; Jordan Kurland