The Interior of Stars III

1. The Interior of Stars III • Stellar Model Building • The Main Sequence

2. Overview: Equations of Stellar Structure • Pressure • Mass • Luminosity • Temperature • http://abyss.uoregon.edu/~js/ast121/lectures/lec22.html HYDROSTATIC EQUILIBRIUM GEOMETRY/ DEFINITION OF DENSITY NUCLEAR PHYSICS THERMODYNAMICS (ENERGY TRANSPORT)

3. Stellar Model Building Equations of Stellar Structure Constitutive Relations • Pressure( equation 10.6) • Mass • Luminosity • Temperature • http://abyss.uoregon.edu/~js/ast121/lectures/lec22.html

4. Stellar Modeling • Difference Equations • Numerical modeling • shells • Boundary Conditions • Analytic Solutions • For SIMPLIFIED conditions!!! • Cow approximated as a sphere!!!

5. Vogt-Russell Theorem • Pressure Gradient at a given radius is dependent on the interior mass and the density. • Radiative temperature gradient depends on the local temperature density, opacity, and interior luminosity. • Luminosity gradient depends on density and energy generation rate. • Pressure ,opacity and energy generation rate depend explicitly on the density, temperature and composition at that location. If interior mass at the surface of the star is specified,along with composition,surface radius and luminosity,application of the boundary conditions at surface P,Mr,T,Lr at a distance dr below the surface Numerical integration gives the rest P(r),Mr (r),T (r),Lr (r),

6. Vogt-Russell Theorem “The Mass and the composition structure throughout a star uniquely determine its radius, luminosity and internal structure, as well as its subsequent evolution”

7. Polytropic ModelsSimplified Assumptions… A good zeroth order approximation for a cow is a ….sphere!

8. Polytropic Models • Stellar Models in which Pressure depends on density in the form • Under special conditions can find analytic solutions to the a subset of the equations descrbing a stellar model • If only a simple relationship existed between pressure and density. The equations of stellar structure 10.6 and 10.7 could be solved without reference to the energy equations

9. Polytropic Models

10. Polytropic Model…

11. Polytropic Models… Relates density and radius….

12. Polytropic Models • Solving 10.110 leads to the profile of density with r. • The pressure profile is obtained from the polytropic equation of state • Assuming the ideal gas law and radiation pressure for constant composition then the temperature profile is obtained

13. Polytropic Models

15. Polytropic Modesl…

16. Polytropic Models

17. The Analytic Solutions to the Lane-Emden Equation

18. Eddington Standard Model

19. Eddington Standard Model…

20. The Main Sequence • Stellar Spectra --> Vast majority of star’s atmospheres are composed primarily from hydrogen • Nuclear burning of hydrogen in its core will cause a “slow” evolution of interior composition. • Most stars with similar initial composition. • The structures of stars should vary smoothly with mass • Low mass stars pp-chain dominates • Higher mass stars CNO cycle dominates • Need at least 0.072 Msun to generate enough pressure to stabilize star • Very massive stars subject to thermal oscillations

21. The Eddington Luminosity Limit • Combining and solving for luminosity we obtain the • Eddington Luminosity Limit • This is the maximum luminosity that the star can have and still maintain hydrostatic equilibrium. If this luminosity is exceeded mass loss occurs…. • Stability of very massive stars directly affected by their high luminosities • In the case of radiation pressure dominating near the surface of a massive star we have for the pressure gradient: • Hydrostatic Equilibrium:

22. Eddington Luminosity limit

23. Models of Main Sequence Stars

24. Computer Modeling…. Star simulation software for your “enjoyment” may be found at the following link.. http://www.physics.utah.edu/~springer/phys3060/Assignments_files/ModernAstrophysicsCode Simulation results may be found at the following link... http://www.physics.utah.edu/~springer/phys3060/Assignments_files/AppendixL

25. Explain This….http://www.solarphysics.kva.se/gallery/movies/oslo-2004/movies/cont6302_20Aug2004_sunspot.mpg

26. The Sun

27. The Sun

28. The Sun • The Solar Interior • The Solar Atmosphere • The Solar Cycle • Theoretical understanding of stellar structure…Now let’s check it… • The Sun is the closest star…Therefore the best studied.

29. High Precision Measurements of properties of Sun • Composition of Sun’s Surface • Luminosity • Effective Temperature • Radius • Magnetic Fields • Rotation Rates • Oscillation Frequencies (vibrations) throughout its interior • Solar Neutrino Production Rate • Allows for rigorous tests of stellar models and our understanding of the physical processes operating within stellar atmospheres and interiors Observations of the Sun Sun viewed in the extreme Ultraviolet http://umbra.nascom.nasa.gov/eit/

30. The Evolutionary History of the Sun • The Sun is classified as a typical main-sequence star of spectral class G2 with a surface composition of X=0.74, Y=0.24 and Z=0.02 (hydrogen,helium and “metals” fractions) • How did the Sun evolve to this point? • The Sun has been converting hydrogen into helium via the p-p chain during most of its lifetime • Composition and structure changes • Stellar Models for the observed composition of the Sun indicate that the Sun should be approximately 4.57x 109 years

31. Present day interior structure of the Sun • Solar Model may be constructed to ascertain features of the interior • This model can be used also to track how the Sun evolves • The mass fraction of hydrogen at the Sun’s center is believed to have started at X=0.71 and has decreased to X=0.34 at the present • The mass fraction for helium at the Sun’s center has increased from Y=0.27 to 0.64 • Diffusive settling has actually increased the fraction of hydrogen at the Sun’s surface by approximately 0.03 and the helium fraction has decreased by 0.03 at the surface

32. Present Day Interior Structure of the SunComposition • The composition of the Sun is no longer homogenous. • Nucleosythesis • Surface Convection • Elemental Diffusion • Composition varies with Radius

33. Energy Production in the Sun • The largest contribution to energy production occurs about 1/10 of the way out from the center of the Sun • This arises from the Mass conservation equation and simple geometry • As you increase radius the volume of a given shell increases as r2 • Even though energy production rate per unit mass may decrease with radius the overall production increases until a maximum shell luminosity is reached at about 0.1 Rsun

34. The Present Day Interior of the SunTemperature and Pressure • Variation of Temperature and Pressure with radius are forced on the solar structure by the following conditions: • Hydrostatic Equilibrium • The Ideal Gas Law • Composition Structure • Boundary conditions at the Surface dictate that both T and P --> 0 there

35. The Present Day Interior of the SunMass and Density • Density decreases rapidly with radius • 90% of mass of Sun contained within one-half of its radius

36. The Present Day Interior of the SunEnergy Transport Mechanism • How is the Energy produced in the “fusion zone” at the center of the Sun transported out? • Radiative transport dominates out to about 0.7 Rsun. • When the temperature gradient becomes superadiabatic • Convection becomes dominant at between 0.7 Rsun out to near the surface

37. Present Day Interior of the Sun • A model of the Sun has been developed using the Stellar Structure Equations and fundamental physical principles that is complete and reasonable that is consistent with: • Evolutionary timescale • Global Characteristics of the Sun • Mass • Luminosity • Radius • Effective Temperature • Surface Composition • Precise Measurements of Oscillation Frequencies (chapter 14) • Observed Surface Convection Zone • Problem: Abundance of Lithium at surface!!!

38. Solar Neutrino Generation Neutrinos allow the interior of the sun to be viewed “directly” but… Solar Neutrino Problem too few solar neutrinos observed. Standard solar model predicted greater neutrino flux that that wasobserved… Resolution:…Neutrino Oscillations. Neutrinos change “flavor” and become undetectable on their flight from the Sun.

39. Solar Neutrino Detection • 615,000 kg of cleaning fluid (100,000 gallons) • One isotope of Chlorine could interact with a neutrino of sufficient energy to produce a radioactive isotope of argon with a half life of 35 days • The threshold energy for this reaction is 0.814 Mev. 77% of the neutrinos above this threshold are from the reaction • about one Argon atom produced every two days!!!! • Chemical analysis used to count argon atoms would measure neutrino flu

40. Solar Neutrino Flux Prediction • John Bachall: Calculated the expected neutrino detection rate for the Davis Chlorine experiment using a model of energy production in the Sun’s interior based on Boron-8 neutrino production in the p-p chain • Why Boron-8? Energy of these neutrinos were above detection threshold of the Chlorine Experiment. • Measured flux about 1/3 of expected flux…What’s going on?

41. Davis Neutrino Flux Measurement

42. Other Neutrino Detectors • Results from these detectors confirmed the deficit of solar neutrino flux observed by the Davis experiment • What’s Going on? • Other detectors with sensitivity to the lower energy neutrinos were developed and built. SAGE, Gallex look for the reaction that converts gallium into germanium • Super-Kamiokande looked for Cerenkov light produced when neutrinos scatter electrons

44. Super-kamiokande

45. Sudbury Neutrino Observatory • http://www.sno.phy.queensu.ca/ • Uses heavy water for detector medium…more sensitive

46. Neutrino Mixing http://en.wikipedia.org/wiki/Neutrino_oscillation#Solar_neutrino_oscillation

47. The Solar Atmosphere Photosphere:Segment of star that emits light. Typically defined to be the region down to an optical depth of 2/3. Chromosphere: In the Sun, a thin layer just above the photosphere that is visually more transparent than the photosphere. The spectrum of the light generated here is dominated by Hwavelength. Temperature of Chromosphere is up to 20,000K. Transition Region: In the Sun, a region between the Chromosphere and Corona. Corona: In the Sun, a type of plasma atmosphere that extends millions of kilometers into space. High temperature.

48. The Solar Atmosphere

49. The Photosphere • Region where the observed optical photons originate is known as the photosphere • Base of photoshpere is wavelength dependent since opacity is wavelength dependent • Base defined to be 100km below where the optical depth of 500nm light is unity. At this depth 500=23.6 and the Temperature is 9400K • The minimum temperature, 4000K, of the photosphere occurs at its upper edge about 525 km above the 500=1 level. Above this point the temperature starts to rise. • On average the solar flux is emitted from optical depth = 2/3 where the effective temperature is 5777K. Why does the solar disk appear sharp?

50. The Solar Disk • Sun Radiates primarily as a black-body in the visible and infrared. • Source of opacity is continuous across wavelength • The continuum opacity is due in part to the presence of H- ions in the photosphere. Only 1/107 H-/neautral hydrogen… • Absorption lines are also produced in the photosphere