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Chapter 8 – Continuous Absorption Physical Processes Definitions Sources of Opacity –Hydrogen bf and ff –H - –He –Scattering.

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Presentation on theme: "Chapter 8 – Continuous Absorption Physical Processes Definitions Sources of Opacity –Hydrogen bf and ff –H - –He –Scattering."— Presentation transcript:

1 Chapter 8 – Continuous Absorption Physical Processes Definitions Sources of Opacity –Hydrogen bf and ff –H - –He –Scattering

2 Physical Processes Bound-Bound Transitions – absorption or emission of radiation from electrons moving between bound energy levels. Bound-Free Transitions – the energy of the higher level electron state lies in the continuum or is unbound. Free-Free Transitions – change the motion of an electron from one free state to another. Scattering – deflection of a photon from its original path by a particle, without changing wavelength –Rayleigh scattering if the photon’s wavelength is greater than the particle’s resonant wavelength. (Varies as -4 ) –Thomson scattering if the photon’s wavelength is much less than the particle’s resonant wavelength. (Independent of wavelength) –Electron scattering is Thomson scattering off an electron Photodissociation may occur for molecules

3 Electron Scattering vs. Free-Free Transition Electron scattering – the path of the photon is altered, but not the energy Free-Free transition – the electron emits or absorbs a photon. A free-free transition can only occur in the presence of an associated nucleus. An electron in free space cannot gain the energy of a photon.

4 Why Can’t an Electron Absorb a Photon? Consider an electron at rest that is encountered by a photon, and let it absorb the photon…. Conservation of momentum says Conservation of energy says Combining these equations gives So v=0 (the photon isn’t absorbed) or v=c (not allowed)

5 What can various particles do? Free electrons – Thomson scattering Atoms and Ions – –Bound-bound transitions –Bound-free transitions –Free-free transitions Molecules – –BB, BF, FF transitions –Photodissociation Most continuous opacity is due to hydrogen in one form or another

6 Monochromatic Absorption Coefficient Recall d  =   dx. We need to calculate , the absorption coefficient per gram of material First calculate the atomic absorption coefficient  (per absorbing atom or ion) Multiply by number of absorbing atoms or ions per gram of stellar material (this depends on temperature and pressure)

7 Bound-Bound Transitions These produce spectral lines At high temperatures (as in a stellar interior) these may often be neglected. But even at T~10 6 K, the line absorption coefficient can exceed the continuous absorption coefficient at some densities

8 Bound Free Transitions An expression for the bound-free coefficient was derived by Kramers (1923) using classical physics. A quantum mechanical correction was introduced by Gaunt (1930), known as the Gaunt factor (g bf – not the statistical weight!) For the nth bound level below the continuum and < n where  0 = 1.044 x 10 –26 for in Angstroms

9

10 Converting to the MASS Absorption Coefficient Multiply by the number of neutral hydrogen atoms per gram in each excitation state n Back to Boltzman and Saha! g n =2n 2 is the statistical weight u 0 (T)=2 is the partition function

11 Class Investigation Compare  bf at =5000A and level T=Teff for the two models provided Recall that and k=1.38x10 -16, a 0 =1x10 -26 And Use the hydrogen ionization chart from your homework.

12 Free-Free Absorption from H I Much less than bf absorption Kramers (1923) + Gaunt (1930) again Absorption coefficient depends on the speed of the electron (slower electrons are more likely to absorb a photon because their encounters with H atoms take longer) Adopt a Maxwell-Boltzman distribution for the speed of electrons Again multiply by the number of neutral hydrogen atoms:

13 Opacity from Neutral Hydrogen Neutral hydrogen (bf and ff) is the dominant source of opacity in stars of B, A, and F spectral type Discussion Questions: –Why is neutral hydrogen not a dominant source of opacity in O stars: –Why not in G, K, and M stars?

14 Opacity from the H - Ion Only one known bound state for bound-free absorption 0.754 eV binding energy So < hc/h = 16,500A Requires a source of free electrons (ionized metals) Major source of opacity in the Sun’s photosphere Not a source of opacity at higher temperatures because H - becomes too ionized (average e - energy too high)

15 More H - Bound-Free Opacity Per atom absorption coefficient for H- can be parameterized as a polynomial in : Peaks at 8500A

16 H - Free-Free Absorption Coefficient The free-free H- absorption coefficient depends on the speed of the electron Possible because of the imperfect shielding of the hydrogen nucleus by one electron Proportional to  3 Small at optical wavelengths Comparable to H - bf at 1.6 microns Increases to the infrared

17 He absorption Bound-free He - absorption is negligible (excitation potential of 19 eV!) Free-free He - can be important in cool stars in the IR BF and FF absorption by He is important in the hottest stars (O and early B)

18 Electron Scattering Thomson scattering: Independent of wavelength In hot stars (O and early B) where hydrogen dominates, then P e ~0.5P g, and  (e) is independent of pressure In cool stars, e- scattering is small compared to other absorbers for main sequence star but is more important for higher luminosity stars

19 Rayleigh Scattering Generally can be neglected But – since it depends on  4 it is important as a UV opacity source in cool stars with molecules in their atmospheres. H 2 can be an important scattering agent

20 Other Sources Metals: C, Si, Al, Mg, Fe produce bound-free opacity in the UV Line Opacity: Combined effect of millions of weak lines –Detailed tabulation of lines –Opacity distribution functions –Statistical sampling of the absorption Molecules: CN -, C 2 -, H 2 0 -, CH 3, TiO are important in late and/or very late stars

21 Molecular Hydrogen Opacity H 2 is more common than H in stars cooler than mid-M spectral type (think brown dwarfs!!) H 2 does not absorb in the visible spectrum H 2 + does, but is less than 10% of H - in the optical H 2 + is a significant absorber in the UV H 2 - ff absorption in the IR

22 Opacity vs. Spectral Type Main Sequence Supergiants

23 Dominant Opacity vs. Spectra Type O B A F G K M H-Neutral H H- Electron scattering (H and He are too highly ionized) He+He Electron Pressure High Low (high pressure forces more H - ) Low pressure – less H -

24 Sources of Opacity for Teff=4500 Log g = 1.5

25 Class Exercise – Electron Scattering Estimate the absorption coefficient for electron scattering for the models provided at a level where T=Teff Recall that and with  in AMU and k=1.38x10 -16 How does  e compare to  Rosseland

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