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Spectral lines

Spectral lines. Photon energy Atomic structure Spectral lines Elements in stars Masses of stars Mass-luminosity relation Reading: sections 16.5, 16.7, 6.2. Photon energy. Up to now, we have been discussing the wavelength of light as determining it color

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Spectral lines

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  1. Spectral lines • Photon energy • Atomic structure • Spectral lines • Elements in stars • Masses of stars • Mass-luminosity relation • Reading: sections 16.5, 16.7, 6.2

  2. Photon energy • Up to now, we have been discussing the wavelength of light as determining it color • However, light comes in discrete packets called photons and the energy of each photon is set by its color or wavelength • From Einstein, we known that the photon energy is inversely proportional to its wavelength

  3. Photon energy

  4. Hydrogen atom Electron orbits around nucleus

  5. Electron orbits From quantum mechanics, only certain orbits are allowed. Each orbit has a specific energy.

  6. How atoms emit light

  7. How atoms emit light • The emitted photon has an energy which is exactly the energy difference between the orbits that the electron had before and after. • Because only certain energies are allowed for the electron orbits, only certain energies of photons can be produced. We call these the spectral lines of hydrogen.

  8. Spectral lines of hydrogen The length of each arrow determines the energy and therefore the wavelength of the photon emitted.

  9. Spectral lines • Each element (hydrogen, helium, neon, mercury, iron, …) has its own particular set of energy levels and its own set of spectral lines. • Do demonstration (7B10.10)

  10. Uses of spectral lines • Because each element has it own unique pattern of spectral lines, the spectral lines from stars can be used to determine the composition, or the relative number of atoms of each elements, of the stars

  11. Kirchoff’s laws • A hot solid, liquid, or dense gas produces a continuous spectrum. • A thin gas in front of a cooler background produces an emission line spectrum. • A thin gas in front of a hot source imprints absorption lines on the spectrum. This is mainly what we see from stars.

  12. Absorption spectrum of a star

  13. Composition of a typical star

  14. Masses of stars • Spectral lines also allow us to measure the velocities of stars via the Doppler shift that we discussed in searching for extra-solar planets. Doppler shift measurements are usually done on spectral lines. • Essentially all of the mass measurements that we have for stars are for stars in binary systems – two stars orbiting each other. • The mass of the stars can be measured from their velocities and the distance between the stars.

  15. Mass-Luminosity relation

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