Chapter 4: Stellar Evolution

Question 1

What are stars formed out of

Answer 1

The interstellar medium
-new stars formed in dense dust and gas clouds
-gravity collapses dust and gas with an angular momentum which becomes a protostar
When protostar becomes hot enough it fused hydrogen atoms
-after millions of years a bipolar flow erupts from protostar and blasts away dust

Question 2

How is energy produced in stars

Answer 2

Through nuclear fusion
E= mc^2

Proton-proton chain (p-p chain)

Question 3

Energy fusion reactions

Answer 3

• difference of mass that disappears from 4H to 1H is called mass defect
• the binding energy is the same energy needed to break the nucleus apart

Question 4

Solar Neutrino problem

Answer 4

• could only detect 1/3 of neutrinos we should
• SNOW lab looked for all three neutrinos and found all of them
• they start as Ve but can change to any Vc or Vu

Question 5

Hydrostatic equilibrium

Answer 5

Keeps stars in balance whilst they have efficient fusion

• pressure balances gravity
• most stars spend most of their lives in this state

Question 6

Most important property of stars

Answer 6

Stellar mass

-governs lifetime, colour, sizes

Question 7

Herzsprung-Russell (colour-magnitude)

Answer 7

• plots stars based on luminosity and temperature(colour)

- main sequence: where most stars on graph due to hydro equilibrium

Question 8

Post main sequence evolution

Answer 8

• formation of red giant
• hydrogen in core runs out
• moves out of hydro equilibrium
• gravity compresses and core heats up
• core gets hotter but she’ll becomes cooler and expands
• starts burning He in the core and H in the shell
• stars higher on the main sequence burn faster
• low mass stars have better convection and low burning so they live longer

Question 9

Elements in stars

Answer 9

• stars start with He and H from which all elements were made from
• near the core elements are placed around like an onion
• these elements are created through nucleosythesis

Question 10

Brown dwarfs

Answer 10

• are failed stars that do not have enough mass
• need a min mass of 0.08M
• they can’t fuse H but can fuse deuterium

Question 11

Death of sun like stars

Answer 11

1-8M

• create a planetary nebula
• surface of red giants become unstable due to weak gravity
• surface temp becomes so low the solid gas forms in atmosphere
• core reactions become unstable
• lose the outer shells of the star and all that’s left if the core (carbon/oxygen)
• geometry of nebula based on rotation of magnetic field

Question 12

White dwarfs and degenerate matter

Answer 12

• stars get very bright and hot for a long time but then they cool down
• becomes a white dwarf which is the end point for stars
• carbon oxygen core
• they have a lot of mass but no temp source so they become degenerate
• the core is being squished with nothing to counter it

Question 13

Pauli exclusion principal

Answer 13

In each energy level only allowed to have two particles with spin up and down
-energy levels are full and locked in place and can not regulate itself

Question 14

The Chandrasekhar limit

Answer 14

As you increase the mass the size gets smaller l

• ends up in a run away reaction
• 1.4 Mo certain mass threshold, where the whole object would collapse

Question 15

Properties of white dwarfs

Answer 15

• a white dwarf in isolation will not grow mass
• In a WD system it overspills the L1 legrangian point where gravities are equal
• the Roche lobe is what gravity dominates
• WDs fill their Roche lobes which causes mass from other star to funnel onto the WD
• this new mass can cause reactions on the surface and it will become unstable and explode in a supernova

Question 16

Supernova

Answer 16

• SNI: no H in its spectrum
• SNII: does have H in spectrum (neutron star)
• Io: specific supernova for white dwarfs in binary system

-SNIa: WD crested from RG (no remnant)

Question 17

Death of most massive stars

Answer 17

8-10Mo

• have high temps for reactions
• mass lost in conversions converted to energy
• energy is released in fission
• create energy by splitting massive elements or fusing light elements
• stars can not create iron in its core so this is the end of the line
• stars collapse due to gravity
• this sends and shock wave and rips away surface of the star
• this is a type 2 supernova

Question 18

Neutron stars

Answer 18

• held up by the degenerate pressure of neutrons
• electrons and protons pushed together it create neutrons
• size of a city
• shrinking into a neutron star increases velocity
• have a magnetic remnant

Question 19

Jocelyn Bell

Answer 19

• found periodic radio pulses
• pulsars are rotating neutron stars where we see pulses of the rotation
• no pressure that can hold matter after neutron degenerates

Question 20

Black holes (stellar mass)

Answer 20

• nothing can hold up its mass
• it collapses and has infinite mass
• if the remnants mass exceeds limit for neutron degeneries, becomes a black hole
• find the stellar mass of black holes through the transfer of material from a star into a black hole
• this makes the accretion disk

Question 21

Schwarzschild radius

Answer 21

• radius of the even horizon

- from the point of singularity to even horizon

Question 22

Einstein’s theory of relativity

Answer 22

• Theory of special relativity: motion near the speed of light
• Theory if general relativity: gravity near large masses

Question 23

Special relativity

Answer 23

The faster an object moves

1. The heavier it becomes
2. The slower time travels
3. The shorter things become

Question 24

General relativity

Answer 24

• equivalence principle: acceleration can be due to being close to a mass and acceleration due to motion. Can’t distinguish between the two
• mass tells space time how to curve and the curvature tells mass how to move and accelerate

Question 25

Bending of starlight (gravitational lensing) rest

Answer 25

• look how the sun bends light
• measure where light begins the sun should be coming from compared to where it is
• use solar eclipse to find this
• also happens when galaxies are in front of quasars
• or by a massive cluster of galaxies

Question 26

Einstein’s rings

Answer 26

When background object is well aligned with foreground lens. Misalignments lead to multiple images

Question 27

Micro lensing

Answer 27

• transient events due to stellar mass objects in galactic halo that cause short time brightening
• helped rule out dark Stellar and sun-stellar mass objects as sources of dark matter

Question 28

Weak gravitation lensing

Answer 28

• measuring dark matter and energy

- when light travels through the universe the shapes change alignment from originally random distribution

Question 29

Bullet cluster

Answer 29

Two galaxies clusters in collision and evidence of dark matter

Question 30

Intra-cluster medium

Answer 30

Gas and dust striped from the cluster in the middle

Question 31

Test 2:

Answer 31

The precession of the perihelion of Mercury. That is, the drifting of Mercury’s closest approach to the sun

• for each orbit of mercury the perihelion change
  
  • 5600”/century (precessing)
  • 5557”/century (from gravity of other planets)
  • 43”/ century (from the dip the sun makes)

Question 32

Test 3: gravitational redshift

Answer 32

• light that comes out of objects uses energy as it climbs out of the potential well
• different from Doppler shift l
• Laser Interfermetric Gravity Wave Observatory