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Stellar Evolution

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Title: Stellar Evolution


1
Stellar Evolution
  • The Birth Death of Stars

2
Chapter 33Section 33.2 and 33.3
  • Star Formation Interstellar Medium
    Protostars.
  • Stars Their Properties.
  • Stellar Death Supernovas, Neutron Stars Black
    Holes.

3
Star Formation
  • The Interstellar Medium is the space between
    stars and is made up of trace amounts of gas(90
    hydrogen, 10 helium) and dust.
  • Regions of this medium are denser than normal and
    are known as nebula for their cloud like
    appearance.
  • It is in these interstellar clouds that stars are
    born.

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Star Formation
  • A shockwave from a supernova can hit one of these
    clouds.
  • This triggers a gravitational collapse, which
    pulls the gas and dust particles together.
  • As the cloud condenses, smaller regions break off
    into globules

7
Star Formation
  • These globules eventually form hot gaseous
    spheres known as protostars.
  • A protostar is not a true star in the sense that
    it has not started burning hydrogen through
    nuclear processes.
  • Gas and dust continue to accrete on the protostar
    and the temperature in the core rises.
  • Once the core reaches 10 million Kelvin, nuclear
    fusion begins.

8
A STAR IS BORN!!!
9
Nuclear Fusion
  • As gravity is pushing inward on the core, nuclear
    fusion is creating energy that pushes outward.
    These forces create an equilibrium that allow the
    star to sustain a definite size and shape.
  • The star is now in a state of hydrostatic
    equilibrium.

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Nuclear Fusion
  • In stars with a core temperature of less than 15
    million K, nuclear fusion occurs via the
    Proton-proton cycle.
  • First step - 2 protons (H nuclei) fuse together
    forming a deuterium nucleus, a neutrino, and a
    positron.
  • Next, the deuterium nucleus fuses with a proton
    and forms an isotope of He.
  • Finally, 2 He isotopes fuse and form a normal He
    atom and 2 protons (H nuclei).

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  • Overall, 4 H nuclei are fused to form 1 He
    nucleus.
  • EMC2 demonstrates that mass and energy are
    interchangeable. This missing mass is released as
    energy.

14
Nuclear Fusion
  • Stars with a core temperature ranging from 15
    million to 100 million K undergo the carbon
    cycle. The overall result is the same as the
    proton-proton cycle, but with different
    intermediates.
  • In stars with a core temperature above 100
    million K, the dominant nuclear process is the
    triple alpha process. 2 alpha particles fuse to
    form Be, and a third alpha particle combines with
    the Be to produce 1 carbon nucleus.

15
Stellar PropertiesLuminosity and Brightness
  • Luminosity (L) - total power radiated in watts.
  • Apparent Brightness (l) - the power crossing unit
    area at the Earth perpendicular to the path of
    the light.
  • l L/4pd2

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Stellar PropertiesParallax
  • How do we measure the distance to stars outside
    of our solar system?
  • The method of parallax is used to measure the
    distance to nearby stars.

18
  • One parsec (pc) is the distance to a star whose
    parallax angle is one second of arc(1?), where
    1?1/3600
  • 1 pc3.26 light-years
  • Distance to Star (in pc)1/parallax(?)

19
Stellar PropertiesH-R Diagram
  • A graph of temperature vs. luminosity with stars
    plotted as single dots.
  • When thousands of stars are plotted, they fall
    into definite regions, suggesting a relationship
    between a stars temperature and luminosity.
  • 90 of stars fall into a band called the main
    sequence which runs from the upper left to lower
    right corners.

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Stellar DeathSmall Stars
  • Some models predict that the smallest red dwarf
    stars may stay on the main sequence for a few
    trillion years.
  • All of these small stars that have ever been born
    are still on the main sequence. We do not yet
    know what happens to them at the end of their
    lives.

22
Stellar DeathMedium Sized Stars
  • Medium sized stars, like our sun, begin to show
    their age as helium builds up in the core.
  • The helium core does not provide any energy and
    gravity causes the core to contract while
    hydrogen continues to fuse in a shell around the
    helium.
  • This gravitational collapse of the core causes
    releases tremendous amounts of heat that causes
    the outer hydrogen shell to expand.
  • At this point, the surface temperature drops and
    the star appears red. It is now known as a red
    giant.

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Stellar DeathMedium Sized Stars
  • The core will continue to collapse due to gravity
    until the temperature reaches 100 million K.
  • At this point, helium begins to fuse into carbon.
    This signals the last stage in a medium stars
    life as there is not energy to fuse carbon into
    heavier elements.
  • The outer shell of the star has such a low
    density that it can drift off into space and form
    a planetary nebula.

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Stellar DeathMedium Sized Stars
  • After the outer shell is gone, the helium
    envelope continues to burn around the carbon
    core.
  • Eventually the helium fuel will run out and
    gravity will once again compress the core.
  • With no source of energy to stop the gravitation
    collapse, the star will shrink until it reaches a
    point called electron degeneracy.
  • The star is now know as a white dwarf and will
    continue to radiate energy until all that remains
    is dead core of ash.

27
Stellar DeathMassive Stars
  • Massive stars follow the same evolutionary track
    as medium sized stars up to the point of the
    carbon core.
  • The core of these massive stars will eventually
    reach 600 million K and carbon will begin to fuse
    and produce oxygen, neon and magnesium.
  • Once the core reaches 1 billion K, oxygen ignites
    and produces silicon.

28
Stellar DeathMassive Stars
  • At 2 billion K the silicon ignites.
  • This process of producing new elements is known
    as nucleosynthesis and is the source of all the
    elements heavier than hydrogen and helium.
  • The human body is made up of 10 hydrogen mass
    with the remaining 90 made up of heavy elements.
    In other words, most of our body is made up of
    materials that were once inside the core of very
    massive stars.

29
Stellar DeathMassive Stars
  • This process of nucleosynthesis will continue
    until the core is made of iron.
  • Iron does not release energy in the fusion
    process but instead requires energy. As the core
    continues to heat up, the iron atoms will simply
    absorb this energy but will not fuse with each
    other.

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Stellar DeathSuper Nova
  • Once the iron core has absorbed the energy from
    the fusion taking place in the outer shells,
    gravity contracts the core together.
  • Eventually the individual particles will be
    packed so tightly they touch each other, at which
    point the collapse is stopped.
  • At this point the star explodes in what is called
    a type II supernova.
  • During these explosions, free neutrons may be
    captured by atoms to produce elements heavier
    than iron.
  • The debris from a supernova can create a nebula.

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Stellar DeathNeutron Stars
  • After a supernova, an extremely dense core of
    neutrons may be left in what is called a neutron
    star.
  • These neutron stars are so dense that one
    teaspoon of material from a neutron star would
    weigh billions of tons.
  • All stars rotate and thus have angular momentum.
    When a star loses most of its mass in a
    supernova, the remaining neutron star rotates
    very quickly.
  • The fastest observed neutron star rotates at 716
    revolutions per second.

34
Stellar DeathBlack Holes
  • A supernova may explode so violently that the
    remaining core is compressed into an infinitely
    small, infinitely dense black hole.
  • Black holes have such a strong gravitational
    pull that even light can not escape if it gets
    any closer than the event horizon.
  • The radius, R, at which a body of mass M must be
    contracted to in order to form a black hole is
    given by R2GM/c2.
  • This radius is given a special name, the
    Schwarzchild radius.
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