Announcements Homework 5 due Monday Solutions to test are posted near south entrance to Science Lab building (until next test) Second test will be next.

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Presentation transcript:

Announcements Homework 5 due Monday Solutions to test are posted near south entrance to Science Lab building (until next test) Second test will be next week (W, Th) Looks like a great weekend for projects! (Due two weeks from today)

Spectroscopy 29 September 2006

Today: Splitting light into separate colors (wavelengths) Spectra of thermal light sources Spectra of nonthermal light sources Absorption spectra How does motion of a light source affect its spectrum?

Thermal Light Sources (Hot, opaque objects) Emit a continuous spectrum (all colors present) Hotter implies brighter Hotter implies bluer in color Brightness & color don’t depend much on what the object is made of Examples: incandescent light filaments (3000 K); electric heating coils (1500 K); coals in a campfire (1500 K); your body (310 K); the sun minus its outer layers (6000 K)

Graphs of thermal spectrum

Orion star colors

Infrared light is real!

Emission Spectra (“nonthermal”) from hot, transparent gases

Hydrogen emission spectrum (“Balmer lines”)

Rosette nebula

Helix nebula

Emission of spectral lines

Hydrogen energy levels Energy -->

Nonthermal Light Sources (Especially hot, transparent gases) Emit only a few precise wavelengths (colors) Temperature matters less than chemical composition Each element has its own spectral “signature” Examples: mercury and sodium vapor lights; lasers (just one wavelength); interstellar gas clouds

Thermal source plus cool gas

Absorption lines in sun’s spectrum

Three types of spectra

Spectrum photo vs. graph

What if a wave source is moving? “Doppler effect”

Doppler-shifted absorption spectra % shift in wavelength = speed of source, as % of speed of light

Doppler-shifted absorption spectra % shift in wavelength = speed of source, as % of speed of light

Doppler-shifted absorption spectra Shorter wavelengths implies it’s moving toward us Wavelengths are shifted by about 10 units (Angstroms) out of 4000, or 1 part in 400. Therefore this object is moving toward us at 1/400 the speed of light (750 km/s)

The Physics of Light Speed = 300,000 km/s Brightness of a source is measured in watts (a unit of power, energy/time) Diffraction indicates wavelike behavior Made of tiny units called photons Wavelength determines color and photon energy Hot, opaque object emits continuous spectrum, brighter and bluer if hotter Hot, transparent gas emits bright-line spectrum Thermal source viewed through cooler gas has dark-line “absorption” spectrum Doppler-shifted spectral lines indicate motion of source toward or away from us