PLANETARY NEBULA
FORMATION
SARANYA V.S
Department of Space Engineering and Rocketry
STELLAR EVOLUTION- MAIN
STAGES
The Collapse of an Interstellar Cloud
Fragmentation into smaller clumps — Stars
Hydrogen Burning -Main Sequence
Helium Burning - Red Giant
Higher “nuclear” fuels (depending on mass)
Death, depending on mass:
Planetary Nebula — White Dwarf
Supernova — Neutron Star
Supernova — Black Hole
DARK NEBULA
Ninety-nine percent of the material in the Universe
is hydrogen and helium. Some of that is locked up
in stars but the vast portion floats in the spaces that
lay between them.
The distances between stellar bodies is huge, the
density of this material is exceedingly thin. some of
it is shepherded by gravity and exploding stars into
enormous nebulous clouds,
COLLAPSE OF INTERSTELLAR CLOUD
Interstellar Medium Contains Clouds.
T~10-100°K, M~10’s-1000’s of Msun
If gravitational pull exceeds gas (and B) pressure, gas
collapses.
PR
OT
OS
TA
RF
OR
MA
TIO
N
EVOLUTION OF STARS / GROSS
FEATURES:
M < 0.08 Msun – Brown Dwarf (no nuclear
burning)
0.08 Msun < M < 0.5 Msun – Central hydrogen
burning. Formation of a degenerate core. No
helium ignition –End as a He white dwarf
0.5 Msun < M < 2 Msun – Central Hydrogen
burning, Helium flash, Helium burning - End as
CO White dwarf.
2 Msun < M < 8 Msun – Central Hydrogen burning,
Helium ignites non degenerately _ End as CO
White dwarf.
8 Msun < M < 20 Msun – Numerous burning stages
after Helium burning. Type II Supernova - ends as
Neutron Star.
20 Msun < M – As above, but ends as a Black
Hole.
Note: High masses are inaccurately known due to
large wind mass loss during evolution
HYDROGEN BURNING
Brown dwarfs
Sub brown dwarfs
Red dwarfs
Super giants
HELIUM BURNING
Low mass star
becomes white dwarf after about 100 billion years
Mid size star
• red giant branch star (inert He core)
• asymptotic giant branch star (inert C core)
formation of planetary nebulae and further becomes
white or black dwarf.
Massive star
undergo supernova explosion and transforms into
neutron star or black hole
RED GIANT EXPANSION
Asymptotic Giant Branch Stars
& Planetary Nebulae
Once He is exhausted in core, core continues to
contract, He & H burn in shells, envelope
expands.
At some point, envelope becomes unstable, and
starts to pulsates, each time shedding some material.
Envelope ejected at ~ 30 km/s, and core contracts
and cools
Envelope becomes planetary nebula
Core becomes white dwarf
PLANETARY NEBULA During the red giant phase, the outer layers of the
star are expelled via pulsations and strong stellar
winds.
The exposed hot, luminous core emits ultraviolet
radiation that ionizes the ejected outer layers of the
star.
This energized shell of nebulous gas reradiates the
absorbed ultraviolet energy at visible frequencies and
appears as a planetary nebula.
Planetary nebula formation
Ring nebula
Lemon slice nebulaNecklace nebula
Crab nebula
Eskimo nebula
Helix nebula
Formation of helix nebula
Cats eye nebula
Bipolar nebulae
Formation of bipolar nebulae
ADVANCED BURNING IN MASSIVE
STARS
Shells:
SUPERNOVAE
One Iron photodisintegration takes place,
core collapses on time scale of 10’s of ms.
At “Low” masses, Neutron star is formed,
and shock appears.
As long as there is large fluxes of infalling
material, shock cannot “leave” the core.
Once shock does propagates outwards
(perhaps using n heating) it:
Heats the envelope (fast nuclear
processes take place (making Trans-
Iron isotopes).
Accelerates the envelope, and it is
ejected with speeds of order 10,000’s
km/s
Cloud Gravitationally Unstable And Starts
Collapsing. Flow Limited By Formation Of Shock
Waves
LEFT OVERS OF MASSIVE STARS
The remnant left can be
either a Neutron Star:
Or a Black Hole!
Neutron stars are held
by degeneracy pressure
of neutrons (and not
electrons)
sun
Neutron star Black hole
If the collapsing stellar core at the
center of a supernova contains
between about 1.4 and 3 solar
masses, the collapse continues until
electrons, protons neutrons are
expelled, producing a neutron star
If the collapsed stellar core is larger
than three solar masses, it collapses
completely to form a black hole: an
infinitely dense object whose gravity
is so strong that nothing can escape its
immediate proximity, not even light
CONCLUSION
Man’s inquisitiveness to know about the outer space has
led to the discovery of several secrets of space. The
formation, evolution and the death of the stars and
nebulae is discussed in this seminar. This topic has
become an interesting topic of research by the scientists
all over the world and covers a vast area of astronomy.
The outer space is limitless…….
And hence the discussion goes on……
Thank you