Conversations with the Earth Tom Burbine
Quiz on Thursday Sun Hertzsprung-Russell Diagram Death of stars
Main Sequence Is not an evolutionary track –Stars do not evolve on it Stars stop on the main sequence and spend most of their lives on it
Sun ends it time on the main sequence When the core hydrogen is depleted, nuclear fusion stops The core pressure can no longer resist the crush of gravity Core shrinks
Why does the star expand? The core is made of helium The surrounding layers are made of hydrogen
And.. Gravity shrinks the inert helium core and surrounding shell of hydrogen The shell of hydrogen becomes hot for fusion This is called hydrogen-shell burning
And … The shell becomes so hot that its fusion rate is higher than the original core This energy can not be transported fast enough to surface Thermal pressure builds up and the star expands
And.. More helium is being created Mass of core increases Increases its gravitational pull Increasing the density and pressure of this region
When When helium core reaches 100 million Kelvin, Helium can fuse into a Carbon nucleus
Helium Flash The rising temperature in the core causes the helium fusion rate to rocket upward Creates a lot of new energy
However The core expands Which pushes the hydrogen-burning shell outwards Lowering the hydrogen-burning shell’s temperature
And Less energy is produced Star starts to contract
Now In the core, Helium can fuse to become Carbon (and some Oxygen) Star contracts Helium fusion occurs in a shell surrounding the carbon core Hydrogen shell can fuse above the Helium shell Inner regions become hotter Star expands
Some carbon fuses with He to form Oxygen 12 C + 4 He → 16 O + gamma ray Harder to fuse Oxygen with Helium to produce Neon
Planetary Nebulae There is a carbon core and outer layers are ejected into space The core is still hot and that ionizes the expanding gas
Planetary Nebulae
White Dwarf The remaining core becomes a white dwarf White dwarfs are usually composed of carbon and oxygen Oxygen-neon-magnesium white dwarfs can also form Helium white dwarfs can also form
High-Mass Stars The importance of high-mass stars is that they make elements heavier than carbon You need really hot temperatures which only occur with the weight of a very high-mass star
Stages of High-Mass Star’s Life Similar to low-mass star’s Except a high-mass star can continue to fuse elements When the fusion ceases, the star becomes a supernova Supernova is a huge explosion
Fusion The temperatures of high-mass stars in its late- stage of life can reach temperatures above 600 million Kelvin Can fuse Carbon and heavier elements Helium Capture can also occur where Helium can be fused into heavy elements
“Deaths” of Stars White Dwarfs Neutron Stars Black Holes
White Dwarfs White Dwarfs is the core left over when a star can no longer undergo fusion Most white dwarfs are composed of carbon and oxygen Very dense –Some have densities of 3 million grams per cubic centimeter –A teaspoon of a white dwarf would weigh as much as an elephant
White Dwarfs Some white dwarfs have the same mass as the Sun but slightly bigger than the Earth 200,000 times as dense as the earth
White Dwarfs Collapsing due to gravity The collapse is stopped by electron degeneracy pressure
Electron Degeneracy Pressure No two electrons can occupy the same quantum state
The Sun Will end up as a White Dwarf
Neutron Star Neutron stars are usually 10 kilometers acroos But more massive than the Sun Made almost entirely of neutrons Electrons and protons have fused together
How do you make a neutron star? Remnant of a Supernova
Supernova A supernova is a stellar explosion. Supernovae are extremely luminous and cause a burst of radiation that often briefly outshines an entire galaxy, before fading from view over several weeks or months.
Type Ia Supernova Type II Supernova
This stops with Iron Fusion of Iron with another element does not release energy Fission of Iron does not release energy So you keep on making Iron
Initially Gravity keeps on pulling the core together The core keeps on shrinking Electron degeneracy keeps the core together for awhile
Then The iron core becomes too massive and collapses The iron core becomes neutrons when protons and electrons fuse together
Density of neutron star You could take everybody on Earth and cram them into a volume the size of sugar cube
Explosion The collapse of the core releases a huge amount of energy since the rest of the star collapses and then bounces off the neutron core Joules Annual energy generation of Sun is Joules
How do we know there are neutron stars? The identification of Pulsars Pulsars give out pulses of radio waves at precise intervals
Pulsars Pulsars were found at the center of supernovae remnants
Pulsars Pulsars were interpreted as rotating neutron stars Only neutron stars could rotate that fast Strong magnetic fields can beam radiation out
Black Holes If a collapsing stellar core has a mass greater than 3 solar masses, It becomes a black hole
Black Hole After a supernova if all the outer mass of the star is not blown off The mass falls back on the neutron star The gravity causes the neutron star to keep contracting
Black Hole A black hole is a region where nothing can escape, even light.
Event Horizon Event Horizon is the boundary between the inside and outside of the Black Hole Within the Event Horizon, the escape velocity is greater than the speed of light Nothing can escape once it enters the Event Horizon
Black Hole Sizes A Black Hole with the mass of the Earth would have a radius of meters A Black Hole with the mass of the Sun would have a radius of 3 kilometers
Can you see a Black Hole?
No Black Holes do not emit any light So you must see them indirectly You need to see the effects of their gravity
Evidence The white area is the core of a Galaxy Inside the core there is a brown spiral- shaped disk. It weighs a hundred thousand times as much as our Sun.
Evidence Because it is rotating we can measure its radii and speed, and hence determine its mass. This object is about as large as our solar system, but weighs 1,200,000,000 times as much as our sun. Gravity is about one million times as strong as on the sun. Almost certainly this object is a black hole.
Any Questions?