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The Doppler Effect

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Spectroscopy
· When the media covers astronomy, they nearly always show pretty pictures. This gives a biassed view of what astronomers actually do: well over 70% of all observations are not pictures - they are spectra. · Spectra are the most vital tool of astronomy - without them we'd be lost. However, they are slightly more complicated to understand than pictures (and nothing like as pretty), so the media ignores them. · Light is made up of waves of entwined electricity and magnetism. This applies to all types of light, including radio waves and X-rays. The general term for these waves is "Electromagnetic Waves". · These waves always travel at the same speed: 300,000 kilometres per second.
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Wavelengths
· Electromagnetic waves, while all travelling at the same speed, can have different wavelengths (the distance between the crest of one wave and the next). · It is the wavelength that determines what type of light you have.
Red Light: Wavelength 700nm

Green Light: Wavelength 550nm

Blue Light: Wavelength 400nm

Ultra-Violet Light: Wavelength 300nm
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The Electromagnetic Spectrum
· Electromagnetic waves can have any wavelengths at all: anywhere from picometres to light-years.
Blue: 400 nm Red: 700 nm

Visible
Gamma Rays 10
-12

X-Rays

UV

Microwaves Radio Waves Infrared UHF FM FM 10
-4

10

-8

1

10

4

Wavelength (metres)

·

These are all basically the same things: waves of entwined electricity and magnetism flying through space: the only thing that's different is the wavelength. You also get waves longer than radio and shorter than Gamma Rays - but these are very rare, and as far as we know useless (at present). Our eyes are only sensitive to visible light. ASTR1001


Spectrographs
· A spectrograph separates light out into its component wavelengths: separating the long wavelength light from the short. · They can either use a prism or a device called a diffraction grating (like the bottom of a cd).
Spectrum White light

Prism (or diffraction grating)

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· We plot spectra as graphs: graphs showing precisely how much power the thing we are looking at emits at each precise wavelength. · Spectra are incredibly useful. Luckily, all chemicals emit and absorb light at certain very specific wavelengths. A typical spectrum (like this spectrum of gas spiraling into a black hole) can be used to identify the composition of the gas.
Nitrogen
Strength of light at this wavelength

Carbon Aluminium

To an expert (like me), every bump and wiggle in a spectrum like this tells a story of what the gas is made of, how it's moving, and how hot it is.
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Wavelength (nm)


What's this got to do with velocities?
· Well, the waves of electromagnetic radiation coming from some distant object can be used to see whether that object is moving away from us or towards us. · If the waves are bunched unusually close together, the object must be moving towards us. This would mean that all the bumps and wiggles in a spectrum would appear to be at slightly shorter wavelengths than usual. · If they are unusually spread apart, the object must be moving away from us. All the bumps and wiggles will be at slightly longer wavelengths than usual. · This effect is called the "Doppler Effect". It is widely used on Earth, for such things as radar and speed traps.

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The Doppler Effect:

and increased here

The wavelength is reduced here

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How does this affect the spectra?
Strength of the Light with this Wavelength Star moving Stationary Star towards from us Star moving away from us

Wavelength
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The Maths
· How big is this effect? A full account requires relativity, but as long as your velocity is a small fraction of the speed of light, the fractional shift in wavelength is equal to the velocity divided by the speed of light.

= f = v fc
Where is the change in the wavelength of some spectral feature, f is the change in its frequency, v is the radial velocity, and c the speed of light.
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Example.
· If, for example, a particular emission line is normally seen at a wavelength of 10 nm, but we observe it in the spectrum of a star at 9nm, then = (10-9). =10, so / = 1/10. · This star must therefore be travelling towards us at 10% of the speed of light.

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