Transcript Supernova
Supernova!
•The fate of stars with mass greater
than 9 solar masses.
•Principally O and B stars.
The context
• Stars like the Sun (M<9 Msolar) recycle
about 50% of their mass back into the ISM
through Planetary Nebula leaving behind a
White Dwarf as a stellar remnant.
• Stars more massive (O and B main
sequence stars) recycle 95% of their mass
back into the ISM through an event called a
super nova (“super star”).
The Event
• Sun-like stars (M< 9 Msolar) stop producing
energy with Shell Helium Burning and
leave behind a carbon core (White Dwarf).
• Stars more massive continue to fuse heavier
elements in their cores as they evolve.
Carbon burning at 600 Million K
Neon burning at 1.2 Billion K
Oxygen Burning at 1.5 Billion K
Silicon Burning at 3 Billion K
…
The Event
• Finally an Iron core with a mass of about 2
solar masses and a radius of 500 kilometers
develops.
• At this stage, the star’s envelope has
swelled to 5 AU (Supergiant).
• The iron core is so dense that its own
gravity causes it to collapse on itself.
Collapse of the Iron Core
• Iron atoms are reduced to individual protons,
neutrons and electrons in a fraction of a second.
• Collapse continues and individual protons and
electrons are squeezed together to form neutrons
and neutrinos.
• In immense flood of neutrinos attempts to leave
the core but cannot escape the incredible dense
matter in the core and they exert an outward
pressure on the star.
Core Rebound
• The collapsing core of neutrons reaches
nuclear density and stiffens.
• The sudden onset of stiffening causes the
collapsing core to rebound and bounce out
to meet the infalling envelope.
• The combined effect of the rebounding core
and the pressure from neutrinos propels the
inner layers of the star outward at near light
speed velocities.
A
Supernova
is formed!
The Implications
• The remains of the star are NOT recycled
back into the ISM but remain as a neutron
star or a black hole.
• These stellar remnants do not emit radiation
and are essentially the end of the line for
these high mass stars.
• Within the exploding envelope of the star
fusion occurs creating new heavy elements.
We are Children of the Stars
• The new heavy elements are dispersed into the
ISM and will later be part of a new star forming
system.
• All elements in the ISM heavier than hydrogen are
created by these supernova.
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Oxygen in the water of our bodies
Carbon in the proteins of our cellular chemistry
Calcium in our bones and teeth
Iron in our hemoglobin
Silicon in the very rocks we walk on
Recall the Aristotelian View of
the Universe.
• The Heavens were a spiritual place that
represented the ultimate source and destination of
mankind.
• In the modern scientific view, the stars are the
physical source of the material that we are made
of, and as the Sun evolves, our ashes will be sent
back into the ISM.
It is understandable that some people have replaced a faithbased religious view with a scientifically-based worldview.
The parallels are clear.
The Standard Candle Concept
• Any astronomical object with a known
luminosity is considered a “standard
candle”.
• When a standard candle is observed it’s
distance can be determined from the
difference between it’s apparent magnitude
and its known absolute magnitude: (m-M).
The
TheStandard
StandardCandle
CandleConcept
Concept
• Supernova’s are good standard candles
because
– They have a uniform peak absolute magnitude,
and
– They are VERY luminous.
• The absolute magnitude of a supernova is
M=-17
How luminous is a Supernova?
• Note that the full Moon has an apparent
magnitude of about –12 and that it can cast
shadows.
• A supernova at a distance of 10 parsecs (32
light years) would appear to be 100 times
brighter than the full Moon!
• It would cast shadows on the Earth from
this distance!
How bright would a supernova be
at various distances?
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At 10 parsecs, m= -17
At 100 parsecs, m= -12
At 1000 parsecs, m= -7
At 10,000 parsecs, m= -2
At 100,000 parsecs, m= 3
At 1,000,000 parsecs, m= 8
With the Hubble Space Telescope that
can “see” to m=28, a supernova can be
seen to a distance of 10 billion parsecs!
Supernova are so luminous that they
are useful standard candles for
exploring the distant (and early)
universe.
What you need to know about
Supernovas for the exam
• What types of main sequence stars will
eventually supernova? What types do not?
• What is the interior of the star like just
before the Supernova event?
• How are supernovas important for the
chemical evolution of the Universe?
• What do astronomers use supernova for?