EVOLUTION OF MASSIVE STARS

Protostar-->Main Sequence-->Subgiant-->Red Giant-->AGB-->Supernova--> Black Hole or Neutron Star



Evolution of A Massive Star

On the Main Sequence, the star generates energy in its core through hydrogen burning using the CNO cycle. While on the Main Sequence, its L slowly increases while its surface T decreases (the star moves to the right and up in the HR diagram).

After the core is cleaned out of hydrogen, it starts to cool and contract slowly. As the core contracts, it heats up and increases in density. This slow contraction causes the overall star to become hotter and slightly more luminous (the star moves to the left and up in the HR diagram).

Next, the region just outside the core gets heated by the shrinking core. Since the region just outside of the core has abundant hydrogen, when its temperature reaches several million Kelvins, hydrogen burning is ignited in a shell outside the core. The formation of this shell source causes the overall star to expand and cool (the star moves to the right in the HR diagram).

Initially, the energy transport in the star is by photons. As the star expands and cools, convection grows in importance. At around a surface temperature of a few thousand Kelvin, convection takes over and the energy leaks out very quickly and the luminosity of the star shoots way up (the star rises almost vertically in the HR diagram). The star is now a Red Giant.

At this time the core is still inert (a slowly contracting ball of helium). When the core finally reaches a temperature of ~ 100,000,000 Kelvin or so, helium burning is ignited. This occurs at the tip of the Red Giant branch. The helium burns through what is called the Triple Alpha Process. An alpha particle is a helium nucleus. The origin of this name is historical in nature.

The ignition of helium causes a decrease in L and an increase in T (causing the star to move down and to the left in the HR diagram). The star settles in this burning stage for a time roughly 10 % as long as its Main Sequence lifetime.

The star then merrily cruises along in this state (helium burning in its core, surrounded by a hydrogen burning shell) until it scours the helium out of its core. The core of the star then cools, and starts to contract in an attempt to replace the heat lost by radiation from its surface. (This causes the star to start moving to the right in the HR diagram again).

Now, just as before when the contracting core heated the surrounding region and caused the ignition of hydrogen in a shell, the contracting core heats the surrounding helium and ignites helium burning in a shell. The star moves again rapidly to the right in the HR diagram.

When the conditions become right for convection to set in, the star rapidly increases in L (and moves almost vertically in the HR diagram). It ascends what is referred to as the Asymptotic Giant Branch (AGB).

It moves up the AGB until the core contracts enough to raise its temperature to the carbon ignition point at the tip of the AGB. When it ignites carbon, the star stops moving upward. Note--the lifetime of the carbon burning state is hundreds of years. This is too fast for the star to make any appreciable changes in its overall structure and so the outward appearance of the star does not change during carbon burning.

When the carbon is scoured out of the core, the core contracts until it can start carbon burning in a shell around the core and neon burning in the core. The neon burning lasts ~ 1 year and so the outward appearance of the star does not change during this phase of evolution. For stars around 10 x the mass of the Sun, the process stops after this phase. For more massive stars, the nuclear processing continues as described next.

For stars more than ~10 x the mass of the Sun, the nuclear game continues to oxygen burning to silicon burning with the total time required for these phases being less than 1 year and so outward evolution of the star is not be visible for these stages.

After silicon burning, the star has an iron (Fe) core surrounded by many active shell sources. The nuclear game stops at this point for stars of any mass. The star runs out of nuclear energy sources and is poised for a catastrophic event.

Illustrative numbers for the evolution of a star 25 times the mass of the Sun. star.


Mass Loss

A large uncertainty in the evolution of massive stars concerns mass loss during the course of their evolution. Hot, massive stars and cool, luminous stars are both sources of prodigous stellar winds; they can lose a solar mass of material on time scale ranging from hundreds of thousands of years to several hundred million years. These sound like long times, but given the time required for stellar evolution, these sorts of rates can affect the way in which stars evolve! The detailed physics by which such winds are generated are not well-understood and usually these effects are included in calculations in rather arbitrary manners. They are usually included by hand.