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To continue to burn hydrogen with all that helium in the way, the core of the star gets a little hotter, the surface
gets a little bigger and the star gets a little brighter .
Course Announcements• Dark night Alternative exercise is posted.• Reports are due Wed. Apr. 22• Final exam (and Exam-4) is (are)
scheduled on Wednesday, May 6, 10:30-12:30pm
• LABS:• This Week: Hubble Red Shift• “On your own”: Galaxy Zoo Classification
• Due: Wed. 29th at class time (NO late labs accepted)
The maximum mass for a white dwarf is 1.4 M, called the Chandrasekhar limit.
If material dumped on the white dwarf pushes it over this limit, it will collapse and explode.
•Electron energy levels crowded together
almost continuous
•All low energy levels are full according to
the Pauli Exclusion Principle
•Only place for additional electrons to go is
in high energy levels which meansthey must move very fast…close tothe speed of light
•Adding more mass decreases the volume
•Temperature is same everywhere
This is called a Type Ia supernova.
The explosion is briefly as luminous as 10 billion Suns.
Nothing of that star is left behind; the other star evolves on its own.
This process requires a binary system.
Concept Quiz—Stages
Which of the following is the correct order for the stages of evolution of the Sun?
A. main sequence, white dwarf, planetary nebula, red giant
B. main sequence, red giant, white dwarf, planetary nebula
C. main sequence, red giant, planetary nebula, white dwarf
D. main sequence, planetary nebula, red giant, white dwarf
Massive stars have more hydrogen to start with but they burn it at a
prodigious rate
The overall reaction is still
224 eHeH
There are 3 gamma ray photons instead of two as in the proton-proton cycle and it consumes
hydrogen much faster
Because energy flow in the core of the star is by radiation, the helium ash isn’t being stirred out.
The central helium core is not fusing. It’s just being squeezed by gravity and added to by the hydrogen fusing above it
A star’s escape velocity decreases once it spreads out:
Sun:
Sun as red giant:
MATH TOOLS 16.2MATH TOOLS 16.2
What happens to planets when stars evolve? Planet migration may allow planets to
survive by moving outward, but some may move inward instead.
Planets have been found orbiting red giants and AGB stars.
As the Sun evolves, Earth’s present location will no longer be in the habitable zone.
Earth may move outward, inward, or stay where it is.
CONNECTIONSCONNECTIONS 16.116.1
Star Formation & LifetimesLecture Tutorial pg. 119
Work with a partner!Read the instructions and questions carefully.Discuss the concepts and your answers with
one another. Take time to understand it now!!!!Come to a consensus answer you both agree on
and write complete thoughts into your LT.If you get stuck or are not sure of your answer,
ask another group.
Type Ia Supernovae over time have become very useful.
This could only happen after more scientists with greater technology analyzed their properties and realized connections.
PROCESS OF SCIENCEPROCESS OF SCIENCE
High-mass stars live different, faster lives. On the main sequence, energy is generated
from the carbon-nitrogen-oxygen (CNO) cycle, with carbon as a catalyst:12C + 4 1H + 2 e = 12C + 4He + gamma rays + neutrinos.
High-mass stars have convection to mix H in the core.
Increases the mass available for fusion.
Once H is exhausted from the core, the star leaves the main sequence and expands and cools.
Move right on the H-R diagram: supergiants.
Ignite He in a nondegenerate core, unlike low-mass stars.
With rising central temperatures, heavier elements (C, Ne, etc.) fuse, generating energy.
The more massive the star, the heavier the elements that can fuse.
As temperature rises and core fuel is used up, heavier and heavier elements will fuse, up until iron.
The fusion shells build up like the layers of an onion.
As high-mass stars expand and cool, they can pass through the instability strip on the HR diagram.
Here, the combination of temperature and luminosity results in the stars’ pulsation.
These pulsating variable stars are extremely important for determining distances.
Specifically, they have a period-luminosity relationship.
Cepheid variables:• High-mass stars
becoming supergiants.• Periods from one to 100
days.• More luminous stars
have longer periods.
RR Lyrae variables:• Low-mass stars on the
horizontal branch.• Less luminous than
Cepheid variables.
Intermediate-mass stars have masses between 3 and 8 M.
Start off evolving as high-mass stars, but finish as low-mass stars do, as white dwarfs.
Very massive stars may shed some mass due to instabilities and go through a luminous blue variable (LBV) phase.
CONNECTIONS 17.1CONNECTIONS 17.1