white dwarfs and neutron stars white dwarfs –degenerate gases –mass versus radius relation...
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White Dwarfs and Neutron Stars
• White dwarfs– Degenerate gases– Mass versus radius relation
• Neutron stars– Mass versus radius relation– Pulsars, magnetars, X-ray pulsars, X-ray
bursters
White dwarf• Core of solar mass star
• Degenerate gas of oxygen and carbon
• No energy from fusion or gravitational contraction
Mass/radius relation for degenerate star
• Star mass = M, radius = R
• Gravitational potential energy =
• Heisenberg uncertainty:
• Electron density
• Kinetic energy
R
GM
5
3 2
px
334
3
Rm
M
R
Nn
p
3131 nx
pnx
235
3522
2 Rmm
M
m
MNK
m
p
pepe
Mass/radius relation for degenerate star
• Total energy
• Find R by minimizing E
• Radius decreases as mass increases
R
GM
Rmm
MUKE
pe
2
235
352
02
2
335
352
R
GM
Rmm
M
dR
dE
pe
35
312
pemGm
MR
Maximum white dwarf mass
• As mass increases, electron speed c, kinetic energy equation E=pc
• Electron degeneracy cannot support a white dwarf heavier than 1.4 solar masses, the “Chandrasekhar limit”.
21
43
33
#
pmG
cM
What happens to a star more massive than 1.4 solar masses?
1. There aren’t any
2. They shrink to zero size
3. They explode
4. They become something else
Neutron Stars
• Degenerate stars heavier than 1.4 solar masses collapse to become neutron stars
• Formed in supernova explosions
• Electrons are not separate– Combine with nuclei to form neutrons
• Neutron stars are degenerate gas of neutrons
Neutron energy levels
• Only two neutrons (one up, one down) can go into each energy level.
• In a degenerate gas, all low energy levels are filled.
• Neutrons have energy, and therefore are in motion and exert pressure even if temperature is zero.
• Neutron star are supported by neutron degeneracy.
Neutron Stars
• Very compact – about 10 km radius
• Very dense – one teaspoon of neutron star material weighs as much as all the buildings in Manhattan
• Spin rapidly – as fast as 600 times per second
• High magnetic fields – compressed from magnetic field of progenitor star
Angular momentum
For single particle, angular momentum L = mvr
Write in terms of rotation rate , v = 2r ,
L = 2mr2 = I ·2
I = “moment of inertia”
In general, I = #MR2
M = mass of object
R = length of object
Spin up of neutron star
Angular momentum of sphere:
2
5
42 MRIL
Where M is mass, R is radius, is spin rate
If the Sun (spin rate 1/25 days, radius 7108 m) were to collapse to a neutron star with a radius of 12 km, how fast would it be spinning?
fffiii MRLMRL 22
5
4
5
4
Spin up of neutron star
fffiii MRLMRL 22
5
4
5
4
15
2
3
817
2
s106.1m102.1
m107s106.4
f
iif R
Rv
Very high rotation rates can be reached simply via conservation of angular momentum.
This is faster than any known (or possible) neutron star. Mass and angular momentum are lost during the collapse.
Pulsars
Discovered by Jocelyn Bell in 1967.
Her advisor, Anthony Hewish, won the Nobel Prize in Physics for the discovery in 1974.
Pulsars
Energy source is spin down of neutron star.
Must lie along pulsar beam to see pulsed signals.
Spin down of a pulsar
222
1Energy IE
dt
dI
dt
dEP
24Power
For Crab pulsar: = 30/s, M = 1.4 solar masses, R = 12 km, and d /dt = – 3.910-10 s-2.
Therefore, P = 7 1031 W = 200,000 solar luminosities.
Over a year, the spin rate changes by only 0.04%.
MagnetarsMagnetic fields so strong that they produce starquakes on the neutron star surface.
These quakes produce huge flashes of X-rays and Gamma-rays.
Energy source is magnetic field.
X-Ray Pulsars
High magnetic field neutron stars make regular pulsations. Energy source is gravitational energy of infalling matter.
X-ray Burst
Low magnetic field neutron stars make X-ray bursts.
Source of energy is nuclear burning.
Review Questions
• What is the exclusion principle?• Does a more massive white dwarf have a
larger or smaller radius than a less massive one?
• What is the maximum mass of a white dwarf?• What are some of the properties of neutron
stars?• Why do many neutron stars spin rapidly?• In what different forms does one find neutron
stars?