Transcript File

Stellar Explosions
Star Ch. 21: Novae,
Supernovae, and the
Formation of the Elements
Standards
• Understand the scale and contents of the
universe, including stars.
• Describe how stars are powered by nuclear
fusion, how temperature and luminosity
indicate their age, and how stellar processes
create heavier and stable elements that are
found throughout the universe.
Life After Death for White Dwarfs
• Becomes a nova – a type of star that may
increase enormously in brightness, by a
factor of 10,000 or more, in a matter of
days.
• Means “new” in Latin. So named because
they seemed to appear suddenly in the
sky.
Life After Death for White Dwarfs
• The white dwarf undergoes an explosion
on its surface that results in a rapid,
temporary increase in luminosity.
• It fades back to normal in a few weeks or
months.
a) Nova Persei
b) Nova Cygni
Life After Death for White Dwarfs
• Recurring novae occur in binary systems.
The dwarf’s gravitational field pulls matter
(hydrogen & helium) from the surface of a
main sequence or giant companion star.
The stolen gas builds up on the surface of
the white dwarf and becomes hotter &
denser, eventually reaching a high enough
temperature to ignite.
White dwarf pulls matter from a red giant
End of a High-Mass Star
• As high mass stars evolve, they fuse
heavier & heavier elements.
• As temperature in the star increases with
depth, the ash of each burning stage
becomes fuel for the next stage.
• The inner core of the star is made of iron,
which is surrounded by shells of silicon,
magnesium, neon, oxygen, carbon,
helium & hydrogen
Layers of star as it fuses heavy elements
Collapse of the Iron Core
• Once the inner core begins to change into
iron, the star is in trouble.
• Nuclear fusion involving iron does not
produce energy because the nuclei are so
compact.
• So, iron plays the role of fire extinguisher,
damping the inferno in the stellar core.
Collapse of the Iron Core
• The central fires cease for the last time,
internal supports dwindle & equilibrium is
gone forever.
• Gravity overwhelms the outward pressure
from fusion and the star implodes, falling
in on itself.
Collapse of the Iron Core
• Core temperature rises to 10 billion
Kelvin, which gives photons enough
energy to split iron into lighter nuclei –
called photodisintegration
• In less than 1 second, the collapsing core
undoes all the effects of nuclear fusion
that occurred during the previous 10
million years.
Collapse of the Iron Core
• As core density rises, protons & electrons
are crushed together to form neutrons &
neutrinos: p+ + e-  no + neutrino: called
neutronization of the core.
• Neutrinos hardly react with matter. They
escape into space carrying away energy.
Collapse of the Iron Core
• Neutrino escape and electron
disappearance make matters worse for
core stability.
• There is now nothing to prevent collapse
to the point at which neutrons come in
contact with one another.
• Contact halts the collapse, but not until
core has overshot point of equilibrium.
Collapse of the Iron Core
• Core becomes compressed, stops, and
then rebounds with a vengeance.
• It takes only 1 second from the start of the
collapse to the “bounce” at neutron
contact.
• An energetic shock wave sweeps through
the star at high speed, blasting all
overlying layers, including heavy
elements outside iron inner core, into
space.
Collapse of the Iron Core
• The star explodes in one of the most
energetic events known, and will shine as
brightly as the entire galaxy in which it
resides for a period of a few days.
• This death of a high mass star is a corecollapse supernova.
Supernova 1987A near the nebula 30 Doradus
Supernova Explosions
• Novae and supernovae are driven by very
different underlying physical processes.
• A supernova is more than 1 million times
brighter than a nova.
• The total amount of energy radiated by a
supernova is equal to the amount of
energy our sun will radiate during its
entire 10 billion year lifetime.
Supernova Explosions
•
A star can nova many times, but a
supernova only happens once to a star.
• Two types of supernovae:
1. Type I: hydrogen poor, formed from the
detonation of a carbon white dwarf
2. Type II: hydrogen rich, formed by the
implosion-explosion of the core of a
massive star (core-collapse supernova)
Supernova Remnants
• Crab nebula: original explosion in 1054
A.D. (observed by Chinese astronomers)
• Could be seen in broad daylight for a
month.
• Is a type II supernova that is expanding
into space at several thousand km/s.
Crab
Supernova
Remnant
Supernova Remnants
• Vela supernova remnant: expansion
velocities imply it exploded around 9000
B.C.
• It is only 500 parsecs from Earth, and may
have been as bright as the moon for
several months.
Vela Supernova Remnant
Supernova Remnants
• Last observed supernova in our galaxy
was Tycho’s supernova in 1572.
• Helped shatter Aristotelian idea of an
unchanging universe.
Tycho’s
Supernova
in x-rays
Formation of the Elements
• Stars’ processes are responsible for
creating much of the world in which we live.
• We currently know of 118 different elements.
• The 81 stable elements found on Earth make
up the bulk of matter in the universe.
• 10 radioactive elements also occur naturally
on our planet.
• 19 radioactive elements have been
artificially produced in nuclear laboratories.
Formation of the Elements
• Hydrogen and most of the helium in the
universe are primordial, that is they date
from the earliest times.
• All other elements in the universe are a
result of stellar nucleosynthesis: they
were formed by nuclear fusion in the
heart of stars. (also by processes
occurring in supernovae)
Formation of the Elements
• Galaxies continuously recycle their matter.
• Each new round of formation creates stars
with more heavy elements than proceeding
generations had.
• The sun is a product of many such cycles.
• We ourselves are another. We are, literally,
made of stars.
• Without the heavy elements synthesized in
the hearts of stars, life on Earth would not
exist.
Stellar
recycling