Post on 19-Jul-2020
Stellar Interiors – Nuclear EnergyASTR 2120
Sarazin
Fusion – the Key to the Stars
Fusion Reactions
log T (K)
Sun
log
ε (e
rg/s
/gm
)
7 7.5
0
8-2
2
4
6
pp
CNO 3αC burning
Thermal Stability of StarsFusion:
Makes lots of energyVery temperature sensitive
hotter more energy
} explosives
BANG
Thermal Stability of StarsWhy don’t stars explode?Stars have negative heat capacity!
Stars have negative heat capacityIf you add energy (heat), they get cooler!!
Energies is Stars
PE = −2 TE
E = − TE 0
TE
E
PE
0
TE
E
PE
Thermal Stability of StarsWhy don’t stars explode?Stars have negative heat capacity!
Add energy, get coolerAdd energy, pressure increases, gas expands, gas
gets coolerCooler è less fusion è less energy
Fusion in stars è perfect thermostat!Stars are incredibly stable!
Thermal Stability of StarsExceptions:1. Virial theorem applies to whole of star
Parts of star exchange energy è pulsations
2. Thermal gas pressure onlyKE = − EKE = (3/2) PV = (3/2) NkT only if P = Pgas
Degeneracy pressure, KE = (3/2) Pdeg V, butPdeg = func. of density only, not temperature
Fusion in degenerate regions è explosion
Fusion – The Key to the Stars
Fusion – The Key to the Stars• Make stellar energy, provide source of light
• Make all heavy elements (C, N, O, Fe, …)
• Make stars stable (or unstable)
• Change composition of stars → they evolve
• Set lifetime of stars, t = Enucl / L
Solar Neutrino ExperimentsASTR 2120
Sarazin
Davis Solar Neutrino Experiment
Tests of Stellar Structure Theory
At some level, all of astronomy (rest of this course)
Critical tests?Sun is good since it is close
Solar Neutrino Experiments
Test idea: Fusion powers starsCannot see into Solar core with light, but
neutrinos should escapeUnfortunately, main neutrinos made by pp
reaction are very low energy, hard to detect
Detect side reactions
Solar Neutrino Experiments
14 Mev!
Solar Neutrino Experiments
Solar Neutrino Experiments
Davis Experiment
Mainly detect 8B n’sn + 37Cl ® 37Ar + e-
Normal chlorine - use 100,000 gal of C2Cl4 (dry-cleaning fluid)
Argon inert, bubble out of tank37Ar decays (beta decay), detect every
single atom!Homestead Gold Mine, South Dakota
Davis Experiment
Davis Experiment
Davis Experiment
Davis Experiment
Predict ~ 5.6 SNU (solar neutrino units)Observe only 1.8 ± 0.3 SNUs ~ 1/3
expectedWhat is wrong?
1. Experiment wrong - No2. Nuclear reaction rates wrong - No3. Astronomy wrong (solar model incorrect)
- No4. Physics wrong - Yes!
Neutrinos are NOT mass-less and stable
Neutrino Oscillations
Three flavors of neutrinos
ne
nµ nt
Neutrino Oscillations
Sudbury Experiment
Super-Kamiokande Experiment
Neutrino Oscillations
Three flavors of neutrinos
ne
nµ nt
Yes!
Nobel Prize 2002
Nobel Prize 2015
Stellar ModelsASTR 2120
Sarazin
Five EquationsdPdr
= −GM (r)ρ
r2 Hydrostatic equilibrium
dMdr
= 4πr2ρ Mass
dLdr
= 4πr2ερ Thermal equilibirum
dTdr
= −min
3κρ64πσ r2
1T 3 L(r) radiation
25TPdPdr
convection
"
#$$
%$$
Energy transport
P = ρkTµmp
+Prad +Pdeg Equation of state
Boundary ConditionsTake radius r as independent variableP(r), T (r), ρ(r), L(r), M (r) 0 ≤ r ≤ R*
Boundary Conditions:Center (r = 0): M (0) = 0, L(0) = 0Surface (r = R*): M (R*) =M*, P(R*) = 0, ρ(R*) = 0Two Problems: 4 differential equations, 5 boundary conditions What is R* ?
Boundary ConditionsChange independent variable to mass Mr(M ), P(M ), T (M ), ρ(M ), L(M ), 0 ≤M ≤M*
dMdr
= 4πr2ρ ⇒ drdM
=1
4πr2ρ
dXdM
=dXdr
drdM
Five (New) EquationsdrdM
=1
4πr2ρ radius (formerly mass)
dPdM
= −GM (r)4πr4 Hydrostatic equilibrium
dLdM
= ε Thermal equilibirum
dTdM
= −min
3κ256π 2σ r4
1T 3 L(r) radiation
25TPdPdM
convection
"
#$$
%$$
Energy transport
P = ρkTµmp
+Prad +Pdeg Equation of state
Boundary ConditionsCenter (M = 0): r(0) = 0, L(0) = 0Surface (M =M*): P(M*) = 0, ρ(M*) = 0Better! 4 differential equations⇔ 4 boundary conditions R* is derived
Vogt-Russell TheoremNecessary inputs:
Mass of star M*
Mean particle mass μ , opacity κ, energy production εDepend on ρ, T, composition
Vogt-Russell Theorem:Star is uniquely determined by mass M* &
composition
Solar Model
T (K3)
ρ (gm/cm3)
ρc = 147 gm/cm3
Tc = 15 million K
Burning hydrogen in core ~ 20% of radius
Radiative zone ~ inner 85% of radiusConvective zone ~ outer 15% of radius
Main SequenceChoice of composition:
Try mainly hydrogen and heliumSurface of Sun and most other starsInterstellar gas è what stars form from
Vary mass M*
Reproduce main sequence (normal stars)All burning H in their coresMain Sequence = stars made of hydrogen
burning H in their cores
Main Sequence
masslow mass
high mass
Main SequenceHydrogen:
Most abundant elementBest nuclear fuelBurned first
Stars spend most of life on main sequence, only leave it when they start to die
Sub-Stellar ObjectsStars Brown Dwarfs Planets
Mass M ≥ 0.075≥ 78 MJ
0.012 ≤ M ≤ 0.07513 MJ ≤ M ≤ 78 MJ
M ≤ 0.012≤ 13 MJ
Fusion? Burn HLater He, C, …
Burn D = 2H deuteriumShort time, then coolDegeneracy pressure
No fusion
M¤ M¤M¤ M¤
Define “star” as self gravitating object which burns hydrogen in its early life
Star M ≥ 100 è blown apart by radiation pressure while forming?
M¤