The Sun Internal structure of the Sun Nuclear
- Slides: 59
The Sun • Internal structure of the Sun • Nuclear fusion – Protons, neutrons, electrons, neutrinos – Fusion reactions – Lifetime of the Sun • Transport of energy in the sun – Radiation versus convection • The atmosphere of the Sun Demos: 8 B 10. 35, 4 B 20. 10
The Sun
The Sun
The Sun
Properties of the Sun • • • Mass = 2 1030 kg Radius = 696, 000 km Luminosity = 3. 8 1026 W Age = 4. 6 billion years Surface temperature = 5, 800 K Composition: 70% H, 28% He, 2% other
Properties of the Sun
Could chemical reactions power the Sun? But the Sun is about 4. 6 billion years old.
Could gravitational contraction power the Sun? Better, but still off by a factor of 100.
Nuclear burning
Nuclear burning Elementary particles • Protons (orange) – found in nuclei, positive charge • Neutrons (blue) – found in nuclei, no charge • Electrons (e-) – orbit nuclei, negative charge • Photons (g) – particles of light (gamma-rays) • Positrons (b+) – anti-matter electrons, positive charge (e+ in book) • Neutrinos (n) – `ghost particles’, no charge, can easily pass through normal matter
Convert proton to neutron • To convert a proton to a neutron • A positron (b+) and a neutrino (n) must be produced and released
Make nuclei out of protons and neutrons 1 H = normal hydrogen nucleus = proton 2 H = deuterium hydrogen nucleus (unstable) = proton plus neutron (in heavy water) 3 He = light helium nucleus (unstable( = two protons plus one neutron 4 He = normal helium nucleus = two protons plus two neutrons
Nuclear burning
Nuclear burning 4(1 H) He 4 + energy + 2 neutrinos MH = 1. 673 10 -27 kg MHe = 6. 645 10 -27 kg Rate of fusion reactions is: Our Sun converts 4 109 kg of matter into energy each second.
Nuclear burning Total energy available is: Lifetime is:
Internal Structure of the Sun We want to make a model of the Sun, what do we need to know?
Gas in the Sun is in hydrostatic equilibrium
Fish in water are in hydrostatic equilibrium
Transport of energy through the radiative zone Photons produced via fusion scatter many times in the Sun’s dense interior - a “random walk”.
Random Walk In one dimension, a random walk can be thought of as tossing a coin: if heads then go left, if tails then go right. Coin tosses follow the binomial distribution. For large numbers of tosses, the distribution becomes the `normal’ distribution. The average total distance traveled for n steps of length l is:
Random Walk The same formula holds in 2 and 3 dimensions. For the Sun, the average distance between collisions is about l = 1 mm. Photons travel at the speed of light, so the time between collisions is t = l/c = 10 -3 m /(3 108 m/s) = 3 10 -12 s The radius of the Sun is L = 7 108 m. The average number of collisions before a photon escapes is n = (L/l)2 = (7 108 m/ 10 -3 m)2 = 5 1023 The average photon stays in the Sun for a time T = tn = (3 10 -12 s)(5 1023) = 1. 5 1012 s = 50, 000 years A more accurate estimate gives 120, 000 years
Q: A drunken pirate takes a 0. 2 m randomly oriented step each second. He starts at the center of a small island of radius 20 m. On average, how long will it take before he steps into the ocean? 1. 2. 3. 4. 5. 20 sec 1000 sec 10, 000 sec 100, 000 sec
Internal Structure of the Sun
Convective zone
Do the following transport energy by convection or radiation? 1. 2. 3. 4. A gas oven A microwave A heat lamp An electric radiator
Internal Structure of the Sun • Equation of hydrostatic equilibrium • Equation of mass continuity • Equation of state • Equations of energy production and transport
Internal Structure of the Sun
How do we know? Core temperature 15, 600, 000 K, density 150 water Surface temperature 5800 K, average density 1. 4 water
How can we check if fusion really powers the Sun
Test fusion hypothesis by looking for neutrinos Neutrinos are only produced in nuclear reactions. Ray Davis shared the 2002 Nobel prize in Physics for originally detecting neutrinos from the Sun.
The Solar Neutrino Problem Neutrinos are detected, but only at 1/3 the rate expected. Solution - Neutrinos change ‘flavor’ as they transit from sun to Earth, from electron neutrinos, to tau ( ) and muon (μ) neutrinos:
We see oscillations on the surface of the Sun
Helioseismology is a way to probe the Sun’s interior using the Sun’s own vibrations. • The surface of the Sun vibrates up and down in oscillations which can go deep through the Sun. • We can observe these oscillations from Earth by looking at the Doppler shifts of different pieces of the Sun.
Waves inside the Sun The pattern of waves on the surface is determined by the conditions deep inside the Sun.
What direct observational evidence supports the model of thermonuclear reactions in the Sun’s core? 1. 2. 3. 4. Neutrinos Gamma rays Sun spot counts WMD inspections
The Sun’s Atmosphere • Photosphere - the 5800 K layer we see. • Chromosphere – a thin layer, a few 1000 km thick, at a temperature of about 10, 000 K. Can be seen during solar eclipse. • Corona – Outermost layer, 1, 000 km thick, at a temperature of about 1, 000 K.
Outer layers of sun 1 = photosphere, 2 = chromosphere, 3 = corona Why the outer layers of the Sun’s atmosphere are hotter is a puzzle.
Photosphere
Chromosphere
Corona
Corona
Limb darkening
Limb darkening
Sunspots are low temperature regions in the photosphere Sun spots are about 4000 K (2000 K cooler than solar surface) and have magnetic fields up 1000 the normal solar magnetic field. They can be as large as 50, 000 km and last for many months.
Particles spiral around magnetic field lines Magnetic field Motion of charged particle (electron, proton, nucleus)
Sunspots are low temperature regions in the photosphere The large magnetic fields in sunspots decrease the flow of heat via convection causing the sunspot to become cool.
Sunspot cycle
Sunspots can be used to measure the rotation of the Sun Near the equator the Sun rotates once in 25 days. The poles rotate more slowly, about once every 36 days.
Sunspot cycle Each 11 years, the Sun’s magnetic field changes direction. Overall cycle is 22 years.
Granulation
Which statement is not correct? 1. The solar coronal temperature is about 106 K. 2. Sunspots are very cool and dark, with temperatures of about 300 K. 3. The Sun’s core has a temperature about 107 K. 4. The chromosphere is hotter than the photosphere.
Solar magnetic fields also create other phenomena • • Prominences Flares Solar wind Coronal mass ejections
Particles spiral around magnetic field lines Magnetic field Motion of charged particle (electron, proton, nucleus) Particles, that we see, get trapped along magnetic field lines, that we don’t see, stretching out from the Sun.
Prominences Cooler than photosphere.
Solar flares Hotter, up to 40, 000 K More energetic
Coronal mass ejections eruption of gas, can reach Earth and affect aurora, satellites Movie
Coronal mass ejection Movie
Aurora
Review Questions 1. How long could the Sun continue to burn H at its current luminosity? 2. What is produced in the fusion of H to He? 3. If the radius of the Sun were doubled, how much longer would it take photons produced in the Sun’s core to escape? 4. What is the connection between sunspots and the Sun’s magnetic field? 5. What is the sunspot cycle?