Difference between revisions of "Radiative Processes in Astrophysics"

An introduction to the basic physics of astronomy and astrophysics at the graduate level. Principles of energy transfer by radiation. Elements of classical and quantum theory of photon emission; bremsstrahlung, synchrotron radiation. Compton scattering, plasma effects, atomic and molecular electromagnetic transitions. With applications to current research into astrophysical phenomena.

These are a collection of lectures covering topics in an introductory graduate astrophysics course on radiative processes. The subject matter is loosely drawn from Radiatve Processes in Astrophysics by Rybicki & Lightman.

At the end of the semester, each student will develop one new lecture on a subject of their choice to add to this website.

Class Code Repository

http://github.com/AaronParsons/astro207

Useful External References

• Rybicki and Lightman, Radiative Processes in Astrophysics (course reference)
• Mihalas and Mihalas, Foundations of Radiation Hydrodynamics
• Osterbrock and Ferland, Astrophysics of Gaseous Nebulae and Active Galactic Nuclei
• Shu, 'The Physics of Astrophysics, Volume I: Radiation
• Longair, High Energy Astrophysics
• Mihalas, Stellar Atmospheres
• Rutten, Radiative Transfer in Stellar Atmospheres
• Eddie Baron's GRK Lectures on Radiation Transport
• Tony Readhead's Notes
• Feynman's Lectures on Physics, Volume II

Topics by Date

(Th, Aug. 27) Intro & Electromagnetic Waves (RL 2.1-2.3; Grif 8.1)

• class mechanics
  • syllabus
  • references
    • Rybicki & Lightman
    • Astrobaki: learn better by teaching
  • tools for figuring stuff out
    • theoretical derivation
    • order-of-magnitude estimation
    • physical intuition (hands-on modeling, analogies)
    • numerical simulation
  • programming
    • Python Installation and Basic Programming
    • Revision Control (class repository)
• Topics
  • Maxwell Equations for Electromagnetic Waves
  • Electromagnetic Plane Waves
  • Energy Density of Electromagnetic Waves
• Activities
  • Astrobaki tour
  • get accounts / set up environments

(Tu, Sep. 1) radiative quantities (RL 1.1-1.3; Mil 1.1-1.3)

• Topics
  • Larmor Formula
  • Specific Intensity
  • Units of radiation
  • Fourier Transform
• Activities
  • estimate Bohr Atom decay
  • convert photon number density to specific intensity
• Problem Set 1 assigned
  • vega_spectrum.dat
  • bessel_V.dat

(Th, Sep. 3) radiative transport (RL 1.4; Mil 2.1-2.2)

• Topics:
  • Radiative Transfer Equation
  • Optical Depth
  • Basic Scattering
• Activities
  • sliding pennies
  • tree leaves
  • locust swarm

(Tu, Sep. 8) thermodynamic equilibrium (RL 1.5)

• Topics
  • Boltzmann distribution
  • Black-Body Radiation (and Kirchoff's Law)
  • Local Thermodynamic Equilibrium
  • Maxwellian velocity distribution
• Activities
  • flipping pennies, rolling dice
  • types of temperature
• Problem Set 2 Assigned

(Th, Sep. 10) semi-classical hydrogen

• Topics:
  • Classical Bohr Atom
• Activities
  • rederivation
  • Rydberg
  • dipoles/quadrupoles

(Tu, Sep. 15) Einstein coefficients

• Topics:
  • Einstein Coefficients
  • Radiative Equilibrium
• Activities
  • estimating Einstein A for Ly-alpha
  • effective photon absorption crosssection
• Problem Set 3 Assigned

(Th, Sep. 17) radiation from accelerating charges (RL 3.3-3.4)

• Topics
  • Estimating Atomic Transition Strengths
  • radiative dipole transitions
  • photoexcitation cross-section
• Activities
  • Einstein A for CO

(Tu, Sep. 22) spectral line broadening

• Topics
  • Line Profile Functions
• Activities
  • continue molecular cloud of CO derivation
  • what can you learn from a spectral line
• Problem Set 4 assigned

(Th, Sep. 24) collisional excitations

• Topics:
  • Collisional Excitations
  • Detailed Balance
• Activities
  • critical densities
  • electron densities in the mesosphere associated with the aurora

(Tu, Oct. 6) free-free emission

• Topics
  • Collisions
  • Thermal Bremsstrahlung (RL 5.1-5.3)
  • Kramer's Opacity
  • larmor radius/frequency
  • cyclotron lines
• Activities
  • collision rates
  • normalizing the maxwellian
  • Heisenberg and the FFT

(W, Oct. 7) radiative equilibrium (RL 1.7-1.8; Mil 2.3-2.5)

• Topics:
  • Coulomb Focusing
  • Central Limit Theorem
  • Thomson cross-section
• Activities
  • timescale for photons/electrons to diffuse through a neutral IGM

(Th, Oct. 8) bound-free transitions

• Topics
  • photoionization
  • Saha Equation
  • Milne Relation
• Activities
  • work out in detail redshift of recombination

(Tu, Oct. 13) LTE and non-LTE

• Topics
  • On-the-spot Approximation
  • statistical equilibrium
  • photoionization equilibrium
  • collisional ionization equilibrium
• Activities
  • estimating recombination coefficients

(Th, Oct. 15) plasma effects

• Topics
  • Plasma Frequency
  • dispersion measure
  • polarization
  • Faraday rotation (RL 8.1-8.2)
• Activities
  • start de-dispersion coding
• Problem Set 5 assigned
  • pulsar.dat

(Tu, Oct. 20) compton scattering

• Topics
  • Lorentz transformations
  • Doppler shift
  • radiation from relativistic charges (RL 4.1, 4.2, 4.8; Grif 10.1)
  • Compton Scattering
• Activities
  • relativistic intuition, velocity raptor

(Th, Oct. 22) Inverse Compton scattering

• Topics:
  • Inverse Compton Scattering
  • SZ Effect (RL 7.1-7.5)
• Activities
  • single scattering versus ensemble scattering
  • compton saturation

(Tu, Oct. 27) relativistic transformations

• Topics:
  • Introduction to Synchrotron Radiation and Relativistic Beaming
  • Synchrotron Frequency
  • synchrotron polarization
• Activities
  • re-deriving synchrotron critical frequency

(Th, Oct. 29) synchrotron radiation

• Topics
  • Synchrotron Power
  • Single Electron Power Spectrum
  • Synchrotron Spectrum (RL 6.1-6.8)
  • Effect of Cooling Time on Synchrotron Spectra
• Activities
  • re-deriving synchrotron spectrum
  • phenomenological description of synchrotron decay

(Tu, Nov. 3) self-absorption

• Topics
  • Synchrotron Self-Absorption
  • Synchrotron Self-Compton
  • Compton Catastrophe
• Activities

(Th, Nov. 5) dust and grains

• Topics:
  • Dust Absorption and Scattering
  • dust formation/sublimation
  • Frequency Redistribution in Non-Coherent Scattering
• Activities

(Tu, Nov. 10) molecular lines

• Topics
  • rotational transitions
  • vibrational transitions
  • H2 & CO
• Activities

(Th, Nov. 12) masers

• Topics
  • Masers
• Activities

(Tu, Nov. 17) radiative diffusion

• Topics:
  • zeeman splitting
  • Radiative Diffusion
  • bolometric radiative equilibrium
  • greenhouse effect
• Activities

(Tu, Dec. 1) high-redshift 21cm radiation

• Topics
  • 21cm Transition
  • Wouthuysen Field effect
  • Radiative Transfer Codes
• Activities

(Th, Dec. 3) Radiative Transfer Codes/Review 1

• Review

(Tu, Dec. 8) Review 2

• Review

Legacy Lecture Notes

1. Radiation Lecture 01
2. Radiation Lecture 02
3. Radiation Lecture 03
4. Radiation Lecture 04
5. Radiation Lecture 05
6. Radiation Lecture 06
7. Radiation Lecture 07
8. Radiation Lecture 08
9. Radiation Lecture 09
10. Radiation Lecture 10
11. Radiation Lecture 11
12. Radiation Lecture 12
13. Radiation Lecture 13
14. Radiation Lecture 14
15. Radiation Lecture 15
16. Radiation Lecture 16
17. Radiation Lecture 17
18. Radiation Lecture 18
19. Radiation Lecture 19
20. Radiation Lecture 20
21. Radiation Lecture 21
22. Radiation Lecture 22
23. Radiation Lecture 23
24. Radiation Lecture 24
25. Radiation Lecture 25
26. Radiation Lecture 26