The Chandrasekhar Limit is approximately 1.4 solar masses (M☉), beyond which electron degeneracy pressure cannot support a star against gravitational collapse, leading to the formation of a neutron star. If the mass exceeds around 3.2 M☉, the neutron star may collapse into a black hole. The limit varies based on the star's remaining mass after significant mass loss during its lifecycle, typically around 5-7 M☉ for main sequence stars. The Oppenheimer-Volkoff limit, which is approximately 2.0-3.2 M☉, also plays a crucial role in determining the fate of neutron stars.
PREREQUISITESAstronomers, astrophysicists, and students of stellar dynamics will benefit from this discussion, particularly those interested in the lifecycle of stars and the physics of compact objects.
aniket said:HI friends,
What is Chandrashekhar limit? HOw is it calculated? Does it remain same for every star? What are its dimensions?
Any suggestions are welcome.
True, a lot of people think of a star's initial mass and should be thinking of the mass remaining after all the mass ejections, usually as a Red Giant. It is always the remaing mass (usually a "core") that should be considered. The Chandrasekhar Limit is well known as 1.44 Ms for most star remaining material (C, N. O, Si, etc,), but he also calculated another for a remaining iron core. This number is 1.39 Ms.ek said:Something the linked reference doesn't mention...
Though the Chandrasekhar limit is 1.4Mo, that is not to say a star 40% more massive than the Sun will become a neutron star. Throughout a star's lifetime and primarily during its death a star loses a lot of its mass through various processes. So while the Chandrasekhar limit is 1.4Mo, the corresponding mass for main sequence stars is actually approximately 5-7Mo. So a star would have to be considerably larger than the Sun to become a neutron star, not slightly more massive as indicated on the surface by the Chandrasekhar Limit.
This same stipulation goes for the Oppenheimer-Volkov limit, which is ~2.0Mo.
So basically what this means is a star with a dying mass of under 1.4Mo becomes a white dwarf, a star of dying mass of between 1.4 and 2.0Mo becomes a degenerate neutron star, and a star of dying mass larger than 2.0Mo becomes a black hole.
Edit: Dying mass is not a technical term. It's just a term I use to differentiate from a star's main sequence mass.
Labguy said:The Oppenheimer-Volkov limit is actually ~3.2 Ms.
aniket said:HI friends,
What is Chandrashekhar limit? HOw is it calculated? Does it remain same for every star? What are its dimensions?
Any suggestions are welcome.
ek said:Can you shed some light on this ambiguity? Is this akin to the Hubble constant in terms of accuracy?
A "minimum mass" for a black hole is not a direct correlation to the maximum mass of a neutron star, but I found the 3.2 Ms # in several books I have. Also it is interesting to note that ~4.25 is the smallest BH detected that I have heard of.SpaceTiger said:Even worse, I would say. The condition of matter (and, thus, the equation of state) in neutron stars is very poorly understood. There are theories that give a variety of numbers, but as far as I know, the observations don't rule out anything much above the Chandrasekhar limit. If anyone knows of some reliable observations of more massive neutron stars, I'd be curious to see the paper.
And the chart at: http://hoku.as.utexas.edu/~gebhardt/blackhole.html has interesting BH masses, but since it is mainly about AGN's, one would expect large masses.The nature of the compact object is based upon its mass. The generally accepted maximum mass of a neutron star is between 3-3.2 solar masses. Therefore, if an object is found with a mass larger than this and it is very compact, it is designated as a black hole.
Last month, Gelino submitted results to the Astrophysical Journal Letters that identify a 4.25-solar mass black hole in the system known as J0422+32, using data from the 3.5-meter telescope at Apache Point Observatory in New Mexico. This system has a separation of just 2.5 solar radii, and is most likely the lowest mass black hole currently known in the Universe.
Labguy said:A "minimum mass" for a black hole is not a direct correlation to the maximum mass of a neutron star
, but I found the 3.2 Ms # in several books I have.
So, if a white dwarf collapses to a neutron star if mass exceeds (accretion?) 1.44 Ms, and anything above ~3.2 Ms will become a black hole, what objects between 1.44 and 3.2 Ms are there?? (legit question)
daveed said:uhh?
they'll be stars, and eventually neutron stars.
ek said:And to the guy who asked the question, remember that while a neutron star is very small radius wise, it is still approximately the same mass as the dying star.
Yes, of course. And as to the 2 posts above I was referring only to masses of remaining cores (matter) at the end of a star's life, as was the subject of this thread. Main sequence stars were not considered in my posts... :zzz:SpaceTiger said:If, by approximately, you mean within a factor of a few. Neutron stars and white dwarfs are what remains of the star's core, the rest having been expelled either by supernova or stellar winds.
If meaning the range of 1.44 to 3.2 Ms, this is where I would expect to find neutron stars even though none have yet been detected near the 3.0 level. That doesn't rule out their existence though. Actually, since it is now known that neutron stars are not composed of only neutrons, have a small "atmosphere" and Nickle/Iron surfaces, I expect that several new types will be found in this mass range such as the "quark" star:LURCH said:Isn't this the range of mass in which stellar remnants are expected to form "Quark stars"?
SpaceTiger said:If, by approximately, you mean within a factor of a few. Neutron stars and white dwarfs are what remains of the star's core, the rest having been expelled either by supernova or stellar winds.
ek said:I thought it was a little less than a factor of a few...like maybe a factor of 2. But you know more than me so I'll believe what you say!