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Transcript
How Stars Evolve
• Pressure and temperature
– Normal gases
– Degenerate gases
• The fate of the Sun
–
–
–
–
–
Red giant phase
Horizontal branch
Asymptotic branch
Planetary nebula
White dwarf
• Reading: sections 21.1-21.3, 22.1-22.3
Pressure and Temperature
• Pressure is the force exerted by atoms in a gas
• Temperature is a measure of how fast the atoms
in a gas move
• Hotter  atoms move
faster  higher pressure
• Cooler  atoms move
slower  lower pressure
Do cold balloon demo
Degenerate gas
• Very high density
• Motion of atoms is not due to kinetic
energy, but instead due to quantum
mechanical motions
• Pressure no longer depends on temperature
• This type of gas is sometimes found in the
cores of stars
The Fate of the Sun
• How will the Sun evolve over time?
• What will be its eventual fate?
Sun’s Structure
• Core
– Where nuclear fusion
occurs
• Envelope
– Supplies gravity to keep
core hot and dense
Main Sequence Evolution
• Core starts with same
fraction of hydrogen as
whole star
• Fusion changes H  He
• Core gradually shrinks and
Sun gets hotter and more
luminous
Gradual change in size of Sun
Now 40% brighter, 6% larger, 5% hotter
Main Sequence Evolution
• Fusion changes H  He
• Core depletes of H
• Eventually there is not
enough H to maintain
energy generation in the
core
• Core starts to collapse
Red Giant Phase
• He core
– No nuclear fusion
– Gravitational contraction
produces energy
• H layer
– Nuclear fusion
• Envelope
– Expands because of
increased energy production
– Cools because of increased
surface area
Sun’s Red Giant Phase
HR diagram
Giant phase is when core has been fully converted to Helium
Helium Flash
• He core
– Eventually the core gets hot
enough to fuse Helium into
Carbon.
– This causes the temperature to
increase rapidly to 300 million K
and there’s a sudden flash when
a large part of the Helium gets
burned all at once.
– We don’t see this flash because
it’s buried inside the Sun.
• H layer
• Envelope
Movement on HR diagram
Movement on HR diagram
Helium Flash
• He core
– Eventually the core gets
hot enough to fuse Helium
into Carbon.
– The Helium in the core is
so dense that it becomes
a degenerate gas.
• H layer
• Envelope
Red Giant after Helium Ignition
• He burning core
– Fusion burns He into C, O
• He rich core
– No fusion
• H burning shell
– Fusion burns H into He
• Envelope
– Expands because of
increased energy
production
Sun moves onto horizontal branch
Sun burns He
into Carbon
and Oxygen
Sun becomes
hotter and
smaller
What happens
next?
Helium burning in the core stops
H burning is continuous
He burning happens in
“thermal pulses”
Core is degenerate
Sun moves
onto
Asymptotic
Giant
Branch
(AGB)
Sun looses mass via winds
• Creates a “planetary nebula”
• Leaves behind core of carbon and oxygen
surrounded by thin shell of hydrogen
• Hydrogen continues to burn
Planetary nebula
Planetary nebula
Planetary nebula
Hourglass
nebula