AstronomyOnline.org
home observation science solar system stars our galaxy cosmology astrobiology exoplanets astrophotography
Stars - High Mass Stellar Evolution

Much of the early stages of the Main-Sequence Turnoff for a high mass star is the same as a low mass star.


(Science Cartoons Plus)

It is important to state that while the fusing of hydrogen to helium is being performed in both low and high mass stars, high mass stars primarily burn hydrogen through the CNO cycle (Carbon, Nitrogen, Oxygen). Carbon acts as the catalyst in the fusion of hydrogen and nitrogen and oxygen absorb the protons to create helium.


If you are looking for professional help with your astronomy academic projects, just buy a research paper written by real experts.

The main reason for this is increased temperature and pressure at the core than a low mass star.

The hydrogen burning shell and helium ash core also exist in the high mass star.

One major difference between a high mass star and a low mass star at this point is the helium flash - there is no flash of helium fusion in a high mass star.

Here is a bit of a summary for high mass stars:


(Image credit: Brooks/Cole Thomson Learning)

The exact stages of evolutions are:

  • Subgiant Branch (SGB) - hydrogen shell burning - outer layers swell
  • Red Giant Branch - helium ash core compresses - increased hydrogen shell burning
  • First Dredge Up - expanding atmosphere cools star - stirs carbon, nitrogen and oxygen upward - star heats up
  • Core Helium Flash - continued compression with added helium ash ignites helium - lots of neutrinos
  • Horizontal Branch - helium burning core - hydrogen burning shell
  • Pre AGB (Asymptotic Giant Branch) - outer layers expand cooling the star - hydrogen shell becomes dormant
  • AGB - re-ignited hydrogen shell burning (like a second Red Giant phase)
  • Several stages of dredge up - nucleosynthesis creates numerous elements (F, Ne, Mg, Al, Li, Ne, Na)

Because a high mass star (> 4 Solar Masses) has considerably more gravity than low mass stars, several shell burning stages can occur:


(Image credit: Brooks/Cole Thomson Learning)

But there is a limit. Iron cannot fuse, and when it tries the end result is a highly compacted core and intense temperatures. The core density is 4 x 1017 kg/m3. This is very degenerate and cannot be compressed further. The intense heat generated by this compression (core bounce) blows the star apart in a type II supernova.

Click on the image to the left to view an animation of a supernova.

In this video, two things happen: the core collapses, explodes and begins to expand while the star collapses (video care of Swinburne Astronomy Online).


(© 2005 Russell Croman, www.rc-astro.com)

The classic supernova remnant is the Crab nebula.

The end result of a supernova is three fold:

  • Heavy elements created in the explosion

  • Intense interstellar wind

  • A neutron star (or black hole) stellar remnant

A white dwarf is the degenerate carbon core of a low mass star. As such, a neutron star is the degenerate iron core of a high mass star.


(Image credit: Brooks/Cole Thomson Learning)

Because if its composition (and energy at the time of compression), intense magnetic energy emanates from the neutron star, and it is spinning rapidly (several thousand times a second).


(Image credit: Brooks/Cole Thomson Learning)

This spinning neutron star is called a Pulsar. At the heart of the Crab nebula is its stellar remnant - a pulsar:

The image above demonstrates how fast a pulsar can spin. What is also interesting is that they are extremely accurate time keepers. A neutron star also emits strong in the X-ray spectrum. Also, just like a white dwarf, a neutron star can accrete material from a companion star, but superheats it to extreme temperature and spins faster.

If the high mass star is around 25 Solar masses, the stellar remnant can compress much further than a neutron star resulting in a Black Hole.

It's important to realize that a black hole is not a hole in space, it's just an object with extremely high surface gravity - but since we have yet to "see" one (and we probably never will), we can only infer their existence by its effect on surrounding matter. A good friend and fellow class-mate wrote an excellent paper going into detail on the subject of Black Holes, and he has graciously allowed me to post it here. So for more information on Black Holes, click Black Holes.

Core Burning Stages in a 25 Solar Mass Star:

Fuel: Products: Temperature (K): Minimum Mass: Burning Period:
H He 4 x 106 0.1 7 x 106 years
He C, O 1.2 x 108 0.4 5 x 105 years
C Ne, Na, Mg, O 6 x 108 4 600 years
Ne O, Mg 1.2 x 109 ~8 1 year
O Si, S, P 1.5 x 109 ~8 ~0.5 years
Si Ni - Fe 2.7 x 109 ~8 ~1 day

Classifications of Supernova:

Type: Characteristics: Mechanism:
1a No H lines, strong Si II lines Thermonuclear runaway on white dwarf
1b No H lines, prominent He I lines Core collapse of massive star stripped of hydrogen envelope
1c No H, Si II or He I lines Core collapse of massive star stripped of helium (and hydrogen) envelope
II-P H lines - flat light curve Core collapse of massive star
II-L H lines - no flat light curve Core collapse of massive star

Back to Top

Search | Site Map | Appendix
©2004 - 2024 Astronomy Online. All rights reserved. Contact Us. Legal. Creative Commons License
The works within is licensed under a Creative Commons Attribution-ShareAlike 3.0 Unported License.