University of California, San Diego
Physics 7 - Introduction to Astronomy
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Physics 7 - Lecture Summary #9
Stellar Evolution I - Solar Type Stars |
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The actual process of
star
formation remains shrouded in mystery
because stars form in dense, cold molecular clouds whose dust obscures newly
formed stars from our view. For reasons which are not fully understood, but
which may have to do with collisions of molecular clouds, or shockwaves
passing
through molecular clouds as the clouds pass through spiral structure in
galaxies, or magnetic-gravitational instabilities (or, perhaps all of the
above) the dense core of a molecular cloud begins to condense under its
self-gravity, fragmenting into stellar mass clouds which continue to condense
forming protostars. As the cloud condenses, gravitational potential
energy is released - half of this released gravitational energy goes into
heating the cloud, half is radiated away as thermal radiation. Because
gravity is stronger near the center of the cloud (remember
Fg ~ 1/distance2) the center condenses more quickly,
more energy is released in the center
of the cloud, and the center becomes hotter than the outer regions. As a
means of tracking the stellar life-cycle we follow its path on the
Hertzsprung-Russell Diagram.
1. Protostar
The initial collapse occurs quickly, over a period of a few years. As the
star heats up, pressure builds up following the Perfect Gas Law:
PV = NRT
where, most importantly P=pressure and T=Temperature. The outward pressure
nearly balances the inward gravitational pull, a condition called
hydrostatic equilibrium.
- Age: 1--3 yrs
- R ~ 50 Rsun
- Tcore = 150,000K
- Tsurface = 3500K
- Energy Source: Gravity
The star is cool, so its color is red, but it is very large so it has a high
luminosity and appears at the upper right in the H-R Diagram.
2. Pre-Main Sequence
Once near-equilibrium has been established, the contraction slows down, but
the star continues to radiate energy (light) and thus must continue to contract
to provide gravitational energy to supply the necessary luminosity. The star
must continue to contract until the temperatures in the core reach high enough
values that nuclear fusion reactions begin. Once nuclear reactions begin in
the core, the star readjusts to account for this new energy source
Gravity releases its potential energy
throughout the star, but due to the very high temperature dependence of the
nuclear fusion reactions, the proton-proton chain is highly centrally
concentrated. During this phase the star lies above the main sequence;
such pre-main sequence stars are observed as
T-Tauri Stars, which are going through a phase of high activity.
Material is still falling inward onto the star, but the star is also spewing
material outward in strong winds or jets as shown in the
HST Photo
below.
- Age: 10 million yrs
- R ~ 1.33 Rsun
- Tcore = 10,000,000K
- Tsurface = 4500K
- Energy Source: P-P Chain turns on.
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Hubble Space Telescope images of young stars called T
Tauri stars in the Pre-Main Sequence phase.
These stars
lie above the Main Sequence in the H-R Diagram. The photos show material
still accreting
onto the star from a protostellar disk; some of this
material is ejected in high velocity jets.
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3. Zero Age Main Sequence
It takes another several million years for the star to settle down on the
main sequence. The main sequence is not a line, but a band in the H-R
Diagram. Stars start out at the lower boundary, called the Zero-Age
Main Sequence referring to the fact that stars in this location have
just begun their main sequence phases. Because the transmutation of Hydrogen
into Helium is the most efficient of the nuclear burning stages, the main
sequence phase is the longest phase of a star's life, about 10 billion yrs
for a star with 1 solar mass.
- Age: 27 million yrs
- R ~ Rsun
- Tcore = 15,000,000K
- Tsurface = 6000K
- Energy Source: P-P Chain in core.
During the main sequence phase there is a "feedback" process that regulates
the energy production in the core and maintains the star's stability. The
basic physical principles are:
- The thermal radiation law, L ~ R2T4, determines the
energy output, which fixes requirement for nuclear energy production.
- The nuclear reaction rates are very strong functions of the central
temperature; Reaction Rate ~ T4 for the P-P Chain.
- The inward pull of gravity is balanced by the gas pressure which is
determined by the Ideal Gas Law: PV=NRT.
A good
way to see the stability of this equilibrium is to consider what happens if we
depart in small ways from equilibrium:
Suppose that the amount of energy produced by nuclear reactions in the core is
not sufficient to match the energy radiated away at the surface. The star
will then lose energy; this can only be replenished from the star's supply of
gravitational energy, thus the star will contract a bit. As the core
contracts it heats up a bit, the pressure increases, and the nuclear energy
generation rate increases until it matches the energy required by the
luminosity.
Similarly, if the star overproduces energy in the core the excess energy
will heat the core, increasing the pressure and allowing the star to do work
against gravity. The core will expand and cool a bit and the nuclear energy
generation rate will decrease until it once again balances the
luminosity requirement of the star.
4. End of Main Sequence
- Age: 10 billion yrs
- Energy Source: P-P Chain in shell around core.
5. Post Main Sequence
- Age: About 1 billion years from Point 4
- R ~ 2.6Rsun
- Tsurface = 4500K
- Energy Source: P-P Chain in shell,
Gravitational contraction of core.
6. Red Giant - Helium Flash
As the Helium core of the star contracts, nuclear reactions continue in a
shell surrounding the core. Initially the temperature in the core is too
low for fusion of helium, but the core-contraction liberates gravitational
energy causing the helium core and surrounding hydrogen-burning shell to
increase in temperature, which, in turn, causes an increase in the rate of
nuclear reactions in the shell. In this instance, the nuclear reactions are
producing more than enough energy to satisfy the luminous energy output.
This extra energy output pushes the stellar envelope outward, against the
pull of gravity, causing the outer atmosphere to grow by as much as a factor
of 200. The star is now cool, but very luminous - a Red Giant.
(You do the arithmetic: 200 x 700,000km = ?; where will the outer radius of
the sun be?)
- Age: 100 million yrs from Point 5
- R ~ 200Rsun
- Tcore = 200,000,000K
- Tsurface = 3500K
- Energy Source: P-P Chain in shell around
core;
Ignition of
Triple-Alpha Process.
The contraction of the core causes the temperature and density to increase
such that, by the time the temperature is high enough for Helium nuclei to
overcome the repulsive electrical barrier and fuse to form Carbon, the core
of the star has reached a state of electron degeneracy. Degeneracy
comes about due to the Pauli Exclusion Principle, which prohibits
electrons from occupying identical energy states. The core of the Red
Giant is so dense that all available lower energy states are filled up.
Because only high-energy states are available, the core resists further
compression -- there is a pressure due to the electron degeneracy. This
pressure has a significant difference from pressure produced by the Ideal
Gas Law -- it is independent of temperature. This removes a key element in
the feedback-stability mechanism that regulates hydrogen burning on the
main sequence.
H-R Diagram from Helium Burning to White Dwarf.
7. Helium Burning Main Sequence
Once again the core of the star readjusts to allow for a new source of energy,
in this case fusion of Helium to form Carbon via the Triple-Alpha Process.
The Triple alpha process releases only about 20% as much energy as hydrogen
burning, so the lifetime on the Helium Burning Main Sequence is only about
2 billion years.
- Age: About 10,000 yrs from point 6.
- Tsurface = 9000K
- Tcore = 200,000,000K
- Energy Source: Triple-alpha process in core;
P-P Chain in shell
During this phase some Carbon and Helium will fuse
12C + 4He --> 16O
resulting in the formation of a Carbon-Oxygen core. When the Helium is
exhausted in the core of a star like the sun, no further reactions are
possible. Helium burning may occur in a shell surrounding thecore for a
brief period, but the lifetime of the star is essentially over.
8. Planetary Nebula
When the helium is exhausted in the core of a star like the sun, the C-O core
will begin to contract again. Central temperatures will never reach high
enough values for Carbon or Oxygen burning, but the Helium and Hydrogen
burning shells will conyinue burning for a while. Throughout the star's
lifetime it is losing mass via a stellar wind, like the solar wind. This mass
loss increases when the star swells up to the size and low gravity of a Red
Giant. During Helium Burning, thermal pulses, caused by the extreme
temperature sensitivity of the 3-alpha Process, can cause large increases in
luminosity with accompanying mass ejection. During Helium Shell Burning, a
final thermal pulse produces a giant "hiccough" causing the star to eject as
much of 10% of its mass, the entire outer envelope, revealing the hot inner
regions with temperatures in excess 100,000K, shown in this
animation of the Helix, below. The
resulting
Planetary Nebuala
is the interaction of the newly ejected shell of gas with the more slowly
moving ejecta from previous events and the ultraviolet light from the hot
stellar remnant, which heats the gas and causes it to fluoresce. The Ring
Nebula in Lyra (Messier
Database, Web
Nebulae) shown here is the prototypical Planetary Nebula. Rather than
a spherical shell as initially believed, the Ring's shape is probably a torus
or cylinder of gas, seen nearly pole-on. Its age is estimated to be a few
thousand years; the central star has a surface temperature over 100,000K.
The Planetary Nebula phase is relatively short lived, estimated to be about
25,000 years, and there are about 10,000 planetaries in the Milky Way.
HST images of Planetary Nebulae:
The
Ring Nebula and the young Planetary Nebula known as
MyCn18, the
Hourglass Nebula.
More about Planetary Nebulare from George Jacoby's (b& w)
Planetary Nebula
Gallery.
Planetary Nebulae
at the SED's Messier Gallery.
The Planetary Nebula Observer's
HomePage includes more
links to Planetary Nebula Resources.
Univ. of Calgary
Planetray Nebula
Homepage with
theoretical models of PN emission structure.
Bruce Balick's
HST Images of Planetary Nebulae.
9. White Dwarf
As the nebula disperses, the shell nuclear reactions die out leaving the
stellar remnant, supported by
electron
degeneracy, to fade away as it cools
down. The white dwarf is small, about the size of the earth, with a density
of order 1 million g/cm3, about equivalent to crushing a volkswagen
down to a cubic centimeter or a "ton per teaspoonful."
- R ~ Rearth (a few thousand km)
- Tsurface = 30000K - 5000K
- Energy Source: "Cooling Off".
A white dwarf star will take billions of years to radiate away its store of
thermal energy because of its small surface area. The white dwarf will slowly
move down and to the right in the H-R Diagram as it cools until it fades from
view as a "black dwarf". To the right is the white dwarf companion to the
nearby star Sirius.
White Dwarf Stars in the globular
cluster 47 Tuc (NASA/HST Photo) - APOD Link
Stellar Evolution #2
Nuclear Reactions
Physics 7 Lectures
Physics 7 Home
Conducted by Gene Smith,
Physics/CASS, UCSD.
Comments?
You may send email to hsmith@ucsd.edu
Prof. H. E. (Gene) Smith
CASS 0424 UCSD
9500 Gilman Drive
La Jolla, CA 92093-0424
Last updated: 27 March 2000
