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- Today: Extra Credit Articles
- Thermal Camera Demo Redux
- Finish Chapter 6
- Chapter 7, the Sun
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- Somewhat complicated – we must correct for temperature effects
- Regular pattern:
- More of the simplest atoms:
H, then He, ...
- Subtle patterns later – related to nuclear fusion in stars
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- Effect similar in light and sound
- Waves compressed with source moving toward you
- Sound pitch is higher, light wavelength is smaller (bluer)
- Waves stretched with source moving away from you
- Sound pitch is lower, light wavelength is longer (redder)
- v = velocity of source
- c = velocity of light (or sound)
- l = apparent wavelength of light
- lo
= original wavelength of
light
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- Car with horn blowing, moving away from you at 70 MPH.
- Speed of sound is ~700 MPH = 1000 ft/sec
- Original horn pitch is 200 cycles/sec Þ lo ~ 5 ft
- Star moving toward you at 200 km/sec = 2.0´105 m/s
- Speed of light c = 3.00 ´ 108 m/s
- Original Ha lo= 0.65647 mm
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- Radius: R = 6.96 ´ 105 km (q=diameter/distance)
- Mass: M = 1.99 ´ 1030 kg
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- Surface Temperature 5800 K (from lmax or spectral type)
- Not all that hot by laboratory standards
- Central Temperature 15 ´ 106 K (explained later)
- Central temperature IS very high
- Luminosity (L) 3.8 ´ 1026 J/s ( L = sT4surface
´ 4 p R2sun)
( L = Fat
Earth ´ 4 p R21 AU)
- Will be important for understanding energy generation in Sun
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- At these T’s, r’s,
hydrogen will be a gas
- At high enough T, as pressure (P) increases and r increases, you never really get a
“liquid”, just a dense gas.
- H ionization?
- On outside, H mostly neutral
(a small fraction is ionized)
- remember H ionized and Balmer lines gone only above 10,000 K
- Over most of interior, H completely ionized
- separate electrons (e-) and protons (p+)
- Ionized gas called a “plasma”
- No discrete “surface” – just increasing r, T, P, and
“opacity”
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- From theory:
- Pressure (P) and density (r) must increase with depth
- Weight of overlying gas compresses lower material --
“Hydrostatic equilibrium”
- Temperature (T) must increase with depth
- Energy is flowing out of the sun – and it flows from hot to cold
-- so hot inside
- Numerical modeling of details let us calculate T(r), r(r), P(r)
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- From observations of “oscillations” or “solar
seismology”
- The sun oscillates like a bell (or the air in an organ pipe)
- The frequency depends upon sound speed, which depends upon T(r), r(r), P(r)
- Observations from “Global Oscillation Network Group (GONG)
telescopes.
- From using Kirchoff’s laws
- The Sun looks like continuous emission: Solid or hot dense gas
- Absorption lines in the spectrum: Cooler gas between us and the dense
gas
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- No discrete “surface” – just increase r, T, P, and
“opacity”
- “Surface” or photosphere defined by depth from which
visible photons can escape.
- Opacity depends on wavelength, so apparent “surface” will be
at different depths for different wavelengths
- High opacity in absorption lines because these photons easily
absorbed/emitted
- Won’t see very far in at these wavelengths.
- Low opacity in between absorption lines
- Can see in deeper at these wavelengths.
- Eventually r so high gas opaque at all wavelengths (just as
in solid)
- “surface” high = cool = dark in lines; deep = hot = bright between
lines
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- We see emission lines at some wavelengths:
- Implies very THIN HOT overlying gas at top of atmosphere
- Gas is so thin it has trouble radiating heat away
- Sound waves or magnetic fields heat thin gas
- Chromosphere (“colored region” glows at a few
wavelengths)
- Corona (“crown” seen during solar eclipses)
- Solar Wind ( escaping wind of tenuous gas)
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- CONVECTION:
- Granulation and Supergranulation
- Heat carried by actual motion of gas
- Different than radiative transport
- energy carried by photons
- dominates deeper in sun
- SUNSPOTS
- Darker (and cooler) regions of sun
- Strong magnetic fields limit convection
- Come and go in 11 (really 22) year cycle
- Magnetic energy releases cause “flares”
- Material ejected causes aurora
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- What holds protons in the nuclei of atoms?
- Coulomb (electric) repulsion should make protons fly apart
- They are packed so close together – must have very strong force
to hold them
- Nuclear “Strong force” attracts nucleons (protons,
neutrons)
- Why doesn’t strong force collapse all atoms into a giant nucleus?
- Nuclear Strong force is very short range
- falls off quickly after a few proton radii
- Coulomb force is long range
- At large distances only coulomb force is important Þ repulsion
- Nuclear Strong Force important only close together
- Requires very high speed (high temperature) collision for fusion
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- If you keep adding protons to a nucleus?
- Coulomb repulsion continues to increase
- new proton feels repulsion from all other protons
- Strong force attraction reaches limit
- new proton can’t feel attraction from protons on far side of a
big nucleus
- Gain energy only up to point where Coulomb repulsion outweighs strong
force attraction.
- Most “stable” nucleus is 56Fe
(26 protons, 30 neutrons, 56 total)
- Release energy by fusion of
light nuclei to make heaver ones– up to 56Fe
- Release energy by fission of heavy nuclei to make lighter ones –
down to 56Fe
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- Why can’t we keep adding neutrons rather than protons?
- They feel strong force attraction – with no Coulomb repulsion
- You should be able to get lots of energy by adding neutrons
- Nuclear Weak Force can (slowly) convert protons to neutrons and back
- The reactions involve an electron or “positron” to keep
charges balanced
- The reactions produce a new almost massless particle called a neutrino
- p+ + e- Û n + n p+ is proton
e- is electron
n is
neutron
n
is neutrino
- p+ Û n + e+ + n e+ is positron = antiparticle of
electron
If this second reaction happens then the positron
annihilates the next electron it encounters, thereby producing
the equivalent of the first reaction.
- The weak force likes to keep ~equal protons and neutrons in a nucleus
- The proton repulsion tips the balance towards slightly more neutrons in
big nuclei
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- Gravity Dominates on astronomical scales
- Electromagnetic Holds atoms together: Chemistry
- Strong force Holds nuclei together: Nuclear energy
- Weak force n Ûp+, e- Radioactive decay
- (will also play critical role in solar fusion)
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- Have lots of hydrogen (p+ and e-) – what can
we make from it?
- If 2He (2
protons, 0 neutrons) were stable, fusion would be “easy”
- Run two protons into each other at fast enough to overcome Coulomb
repulsion
- Once they get close enough strong force takes over, and holds them as
nucleus
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- “Unfortunately” 2He isn’t stable
- To get stable He need to add one or two neutrons to:
- Increase Strong Force, without increasing Coulomb force
- Not really “unfortunate” – If 2He were
stable:
- Sun would burn energy way too fast – and would have gone out by
now
- Weak force converts proton to neutron–fusion will be slow
- In solar fusion no excess neutrons lying around
- Hydrogen bombs use deuterium: 2H = (p+ n) or
tritium: 3H = (p+
n n) to provide it
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- The first step is slow because it relies on two rare events happening
simultaneously
- Two protons collide with enough energy to overcome the Coulomb barrier
- While they are close the weak force turns one proton into a neutron
- The resulting combination of a proton and a neutron IS a stable
nucleus
- 1H + 1H ® 2H + e+ + n p+ + p+ ® (p+
n) + e+ + n
- The next two steps go quickly because they
rely only on the strong force
- 2H + 1H ® 3He (p+
n) + p+
® (p+ n n )
- 3He + 3He ® 4He + 1H + 1H
(p+ n n) + (p+ n n) ® (p+ p+
n n) + p+ + p+
- The net effect is
4 1H ® 4He
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- Could work it out “classically” by strength of forces
- Classical mechanics doesn’t work at this scale – Need
quantum mechanics
- Strength of nuclear forces not originally known
- Use E=mc2 to do accounting
- Mass is a measure of the energy stored in a system
- Loss of mass from a system means release of energy from that system
- Compare mass of four 1H to mass of one 4He
- 6.693 ´ 10-27
kg - 6.645 ´ 10-27 kg = 0.048 ´ 10-27 kg
drop in mass
- E = mc2 = 0.048 ´ 10-27 kg ´ (3 ´ 108 m/s)2 = 0.43 ´ 10-11 kg m2/s2
= 0.43 ´ 10-11 J
(note == a Joule is just shorthand for kg m2/s2)
- So 4.3 ´ 10-12
J of energy released
- This is huge compared to chemical energy: 2.2 ´10-18 J to ionize hydrogen
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- Luminosity of sun: 3.8 ´ 1026
J/s
- H burned rate:
- H atoms available:
- Lifetime:
- In reality not all the atoms we start with are H, and only those near
the center are available for fusion. The structure of the sun will
change when about 10% of the above total have been used, so after about
10 billion years.
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- Does lifetime of sun make sense?
- Oldest rocks on earth ~4 billion years old
- Oldest rocks in meteorites ~4.5 billion years old
- Other stars with higher/lower luminosity
- Causes for different luminosity
- Lifetimes of those stars
- Look for neutrinos from fusion
- Complicated story – due to neutrino properties
- Example of how astronomy presents “extreme” conditions
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- Generated by “weak” force during p+® n + e+
+ n
- “Massless” particles which
interact poorly with matter
- In that first respect, similar to photons
- Can pass through sun without being absorbed
- Same property makes them very hard to detect
- Davis experiment at Homestake Mine in Black Hills
- 100,000 gallon tank of C2Cl4 dry cleaning fluid
- in Cl nuclei n + n ® p+ + e- so Cl (Z=17) becomes Ar (Z=18)
- Physically separate out the Ar, then wait for it to radioactively decay
- Saw only 1/3 the neutrinos predicted
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- Lack of solar neutrinos confirmed by Kamiokande II detector in
Japan. (Using different
detection method)
- Apparent explanation in terms of Neutrino physics
- 3 different types of Neutrinos:
- electron, muon, and tau neutrinos
- Sun generates and Cl detectors see only electron neutrinos
- Can electron neutrinos can change to another type on way here?
- These “neutrino oscillations” are seen and imply neutrino
has non-zero mass
- Kamiokande II evidence of muon neutrinos becoming electron ones
- Read “Window on Science 7-2” on “scientific faith”
- Neutrino mass may have implications for “cosmology”
- Neutrinos also used to study supernova 1987A
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