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Light and telescopes

Light and telescopes. Just by analyzing the light received from a star, astronomers can retrieve information about a star’s. Total energy output Surface temperature Radius Chemical composition Velocity relative to Earth Rotation period. What is light?. Electricity. Magnetism.

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Light and telescopes

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  1. Light and telescopes Just by analyzing the light received from a star, astronomers can retrieve information about a star’s • Total energy output • Surface temperature • Radius • Chemical composition • Velocity relative to Earth • Rotation period

  2. What is light?

  3. Electricity

  4. Magnetism

  5. Electromagnetic induction Time-dependent magnetic field creates time-dependent electric field, and vice versa

  6. Electromagnetic waves

  7. Light as a Wave (1) l c = 300,000 km/s = 3*108 m/s • Light waves are characterized by a wavelength l and a frequency f. • f and l are related through f = c/l

  8. Wavelengths and Colors Differentcolors of visible light correspond to different wavelengths.

  9. The Electromagnetic Spectrum Wavelength Frequency High flying air planes or satellites Need satellites to observe

  10. Light as a Wave (2) • Wavelengths of light are measured in units of nanometers (nm) or Ångström (Å): 1 nm = 10-9 m 1 Å = 10-10 m = 0.1 nm Visible light has wavelengths between 4000 Å and 7000 Å (= 400 – 700 nm).

  11. Light as Particles • Light can also appear as particles, called photons (explains, e.g., photoelectric effect). • A photon has a specific energy E, proportional to the frequency f: E = h*f h = 6.626x10-34 J*sis the Planck constant. The energy of a photon does notdepend on the intensity of the light!!!

  12. Dual, wave-particle nature of light 1 eV = 1.6x10-19 J c = 3x108 m/s 1 Angstrom = 10-10 m Speed of light in matter: cm = c/n, where n is refractive index Note: n is a function of 

  13. Stars are hopelessly far away … Matter in space consists of the same atoms as matter on Earth Physical laws should be the same We can still learn something about the stars!

  14. Optical Telescopes Astronomers use telescopes to gather more light from astronomical objects. The larger the telescope, the more light it gathers.

  15. Refractors and Reflectors (SLIDESHOW MODE ONLY)

  16. Refracting/Reflecting Telescopes Refracting Telescope: Lens focuses light onto the focal plane Focal length Reflecting Telescope: Concave Mirror focuses light onto the focal plane Focal length Almost all modern telescopes are reflecting telescopes.

  17. Disadvantages of Refracting Telescopes • Chromatic aberration: Different wavelengths are focused at different focal lengths (prism effect). Can be corrected, but not eliminated by second lens out of different material. • Difficult and expensive to produce: All surfaces must be perfectly shaped; glass must be flawless; lens can only be supported at the edges

  18. 140-ft Hevelius telescope 1673

  19. Newton’s telescope: the first reflecting telescope

  20. Telescope parameters • Light-gathering power (ability to see faint objects) • Resolving power (ability to see fine details) • Magnification (least important)

  21. The Powers of a Telescope:Size Does Matter 1. Light-gathering power: Depends on the surface area A of the primary lens / mirror, proportional to diameter squared: D A = p (D/2)2

  22. The Powers of a Telescope (2) 2. Resolving power: Wave nature of light => The telescope aperture produces fringe rings that set a limit to the resolution of the telescope. Resolving power = minimum angular distance amin between two objects that can be separated. amin = 1.22 (l/D) amin For optical wavelengths, this gives amin = 11.6 arcsec / D[cm]

  23. Interference and diffraction

  24. Resolution and Telescopes (SLIDESHOW MODE ONLY)

  25. The Powers of a Telescope (3) 3. Magnifying Power = ability of the telescope to make the image appear bigger. The magnification depends on the ratio of focal lengths of the primary mirror/lens (Fo) and the eyepiece (Fe): M = Fo/Fe A larger magnification does not improve the resolving power of the telescope!

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