Collapsing Stars on the H-R diagram

In summary, a star needs a minimum amount of mass to collapse into a black hole. The dividing line between a star that will collapse and a star that won't is unknown, but is thought to be somewhere in between 1.5 and 3.0 solar masses. Stars that are over 40 solar masses will not collapse, while those under 15 solar masses will result in a neutron star. The process of collapse is very complicated and is done using computer simulations.
  • #1
Zems
5
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Hi, I've been looking at the Hertzsprung-Russel diagram and was wondering exactly what types of stars collapse to form a black hole? What temperature range/radius etc. turn into black holes. I understand that its most likely the supergiants that form black holes, but what about the giants? Are they too small?
 
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  • #2
A giant star is simply a star with greater radius and luminosity than a main sequence star of equal temperature. It doesn't have anything to do with the mass. However, stars do need a minimum of mass to reach the giant stage. According to wikipedia they need greater than 0.25 solar masses.

For a star to collapse into a black hole, the core needs a minimum amount of mass when it reaches the point where it can no longer hold itself up over gravity. I believe this is somewhere between 1.5 - 3.0 solar masses. Note that this is the mass of the core, not the entire star itself. A large percentage of a stars mass will be ejected in the supernova of the collapse, with only the core itself actually collapsing. I would guess that SOME giants can collapse into a black hole, but I really don't know the required inital mass range a star needs.


Interestingly, stars above a certain mass will actually blow themselves apart from the core outwards without leaving a neutron star or black hole, meaning that black holes can only form from stars in a range of masses with a minimum and maximum value.
 
  • #3
Zems said:
Hi, I've been looking at the Hertzsprung-Russel diagram and was wondering exactly what types of stars collapse to form a black hole? What temperature range/radius etc. turn into black holes. I understand that its most likely the supergiants that form black holes, but what about the giants? Are they too small?

We don't know enough about how supernova work to know the exact dividing line. We are pretty sure that things over 40 solar mass will end up as a black hole and things that are under 15 solar masses will end up as a neutron star. Where the exact dividing line is, we don't know.

Also it could be different for different stars. If a large star has a lot of mass loss because of it's environment, it could behave differently than a small star that doesn't.
 
  • #4
Drakkith said:
AFor a star to collapse into a black hole, the core needs a minimum amount of mass when it reaches the point where it can no longer hold itself up over gravity. I believe this is somewhere between 1.5 - 3.0 solar masses.

This is one of the uncertain things. In order to calculate that number we need to know how "stiff" nuclear material is, and we don't. If nuclear material is stiff they you need more of it to collapse into a black hole.

A large percentage of a stars mass will be ejected in the supernova of the collapse, with only the core itself actually collapsing. I would guess that SOME giants can collapse into a black hole, but I really don't know the required inital mass range a star needs.

That's cool. No one else does either. We don't know enough about supernova and massive star evolution to go from initial mass to final mass. We know enough to set some limits (i.e. 10 solar mass will not be a black hole. 40 solar mass will), but we don't know enough to figure out the details.

One of the things that I wanted to do with my Ph.D. dissertation was to figure out what the limit was. After seven years of doing my dissertation, I came to the conclusion that what I was doing wouldn't come up with the answer, and so this is a mystery of the universe that someone else needs to take a crack at.

Most of these calculations are done using computer simulations, which can be quite complicated.

Interestingly, stars above a certain mass will actually blow themselves apart from the core outwards without leaving a neutron star or black hole, meaning that black holes can only form from stars in a range of masses with a minimum and maximum value.

That's about 100 solar mass at which point you get a weird pair-production supernova. Also stars in the early universe when there was nothing other than hydrogen/helium are likely to behave very differently than stars today.
 
  • #5
Exactly twofish! So interesting!
 
  • #6
thanks for all the replies, it was very enlightening. I would like to know about your thesis twofish-quant.
 

What is the H-R diagram?

The Hertzsprung-Russell (H-R) diagram is a graph that shows the relationship between the luminosity (brightness) and temperature of stars. It is a fundamental tool for understanding stellar evolution and is used by scientists to classify and study different types of stars.

What do collapsing stars look like on the H-R diagram?

Collapsing stars, also known as supernovae, appear as bright and hot spots on the H-R diagram. They are often located in the upper left corner of the graph, indicating high luminosity and temperature.

Why do stars collapse?

Stars collapse when they run out of fuel to maintain their nuclear fusion reactions. This causes the core to contract, increasing the temperature and pressure until the star explodes in a supernova event.

What happens to collapsing stars after they explode?

After a supernova event, most of the star's material is expelled into space, leaving behind a dense core known as a neutron star or black hole. These remnants can often be seen on the H-R diagram as dim and cool objects.

What can we learn from studying collapsing stars on the H-R diagram?

Studying collapsing stars on the H-R diagram allows scientists to understand the life cycle of different types of stars and the processes that drive their evolution. It also provides insights into the composition of the universe and the formation of new stars and galaxies.

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