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Stars Introduction To “Atomic Astrophysics and Spectroscopy” (AAS) Anil Pradhan and Sultana Nahar Cambridge University Press 2011 Details at: www.astronomy.ohio-state.edu/~pradhan/Book/book.html.

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Presentation on theme: "Stars Introduction To “Atomic Astrophysics and Spectroscopy” (AAS) Anil Pradhan and Sultana Nahar Cambridge University Press 2011 Details at: www.astronomy.ohio-state.edu/~pradhan/Book/book.html."— Presentation transcript:

1 Stars Introduction To “Atomic Astrophysics and Spectroscopy” (AAS) Anil Pradhan and Sultana Nahar Cambridge University Press 2011 Details at: www.astronomy.ohio-state.edu/~pradhan/Book/book.html www.astronomy.ohio-state.edu/~pradhan/Book/book.html

2 The Sun – X-Ray Image (YOHKOH Satellite) Though the surface temperature of the Sun is 5,770 degrees Kelvin, the Sun is surrounded by very hot gas in the solar corona at more than a million degrees. Solar flares and coronal mass ejections (CMEs) frequently erupt from the Sun emitting intense radiation and charged particles.

3 Structure of the Sun: Three Zones Core, Radiative, Convective Energy is produced in the core via thermonuclear reactions and radiates out through the star Radiation diffuses through the Radiative zone via light- matter interactions Convection occurs in the outer- most regions before radiation emerges through the stellar atmosphere (not shown)

4 Brightness and Temperature Brightness is the total energy emitted, or the luminosity of an object The luminosity is related to the (blackbody) temperature of the object L =  T 4  is a constant) Stefan-Boltzmann Law where T is the temperature in thermal equilibrium (like an oven or a star) The Sun is nearly a blackbody at 5,550 K (Fig. 10.1, AAS)

5 Color Indicates Temperature and Energy of the Source Objects generally emit radiation at all wavelengths, but mostly at one peak wavelength depending on their temperature (e.g. blue – hot, red – cool) Surface T (Sun) = 5700 K Blackbody: Perfect absorber and emitter of radiation at Temperature T

6 Color vs. Peak emission wavelength (energy)

7 Colors of stars

8 Stars are labeled according to color-temperature-luminosity (O – L)

9 The Hertzsprung-Russell (HR) Diagram The HR diagram assigns stellar temperature (color) to spectral classes (bottom and top), related to luminosity (left) measured in absolute magnitudes (right)

10 Temperature vs. color (visible/blue)

11 Luminosity Classes I – V and Spectral Types O-M  he Sun is a G2V star

12 Stellar classes (cf. Fig. 10.2, AAS)

13 Luminosity vs. Spectral Class (color-temperature): O,B,A,F,G,K,M Thermonuclear fusion drives stellar activity, structure, and properties (Ch. 10-11, AAS). Most stars spend most of their lives on the Main Sequence in the H  He “burning” phase, fusion of hydrogen into helium which converts some mass into energy according to the Einstein relation E = mc 2. The Hertzsprung-Russell Diagram

14 Visible Spectrum: Balmer Series of Absorption Lines of H HH HH

15 Spectrum of A1 Star: Strong H Lines

16 Spectrum of a G0 Star: No H, neutral and ionized metals Temperature About 6000K. The Sun is a G2 star. See Fig. 1.1 in AAS on Fraunhofer lines in the Sun, and Fig. 10.3 on G to K spectral types.

17 Atoms and Stellar Spectral Types

18 Colors and Spectral Types of Some Stars

19 Summary of spectral properties of stars (c.f. Table 10.1, AAS) With decreasing T observed spectra reveal Ions  Neutral Atoms  Molecules

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