1. Discussion slide- info from http://science. hq. nasa
Have you ever seen a flag on a windy day? The wind creates waves in the flag.
Have you ridden an ocean wave?
You can see them
You can feel them
You can make them
There are other kinds of waves. We cannot see these waves, but we experience them every day. Sound waves and electromagnetic waves are examples of invisible waves. Sound can travel through anything made of molecules - even water! Electromagnetic waves are different from sound waves because they do not need molecules to travel. This means that electromagnetic waves can travel through air and solid materials - but they can also travel through empty space.

4. Electromagnetic Waves- EM
Electric wave is Blue
Magnetic wave is Red

5. What do Radio Waves show us?
Many astronomical objects emit radio waves, but that fact wasn't discovered until Since then, astronomers have developed sophisticated systems that allow them to make pictures from the radio waves emitted by astronomical objects. Radio telescopes look toward the heavens at planets and comets, giant clouds of gas and dust, and stars and galaxies. By studying the radio waves originating from these sources, astronomers can learn about their composition, structure, and motion. Radio astronomy has the advantage that sunlight, clouds, and rain do not affect observations.

6. Electromagnetic Spectrum
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How are electromagnetic waves different?
Wavelength- Distance from one crest to the next crest in a wave
Frequency- number of waves in a set amount of time.

7. Wavelength increases or decreases?
Frequency increases or decreases?

14. Radio waves image of the Sun Microwave image of the Sun
By studying the radio waves, astronomers can learn about the composition, structure, and motion of components of the universe. Radio astronomy has the advantage that sunlight, clouds, and rain do not affect observations.
Microwaves penetrate haze, light rain and snow, clouds, and smoke and are beneficial for satellite communication.

15. Infrared image of the Sun Visible light image of the Sun
Many objects in the universe are too cool and faint to be detected in visible light but can be detected in the infrared. Scientists are beginning to unlock the mysteries of cooler objects across the universe such as planets, cool stars, nebulae, and many more, by studying the infrared waves they emit. Infrared waves have longer wavelengths than visible light and can pass through dense regions of gas and dust in space with less scattering and absorption. Thus, infrared energy can also reveal objects in the universe that cannot be seen in visible light using optical telescopes.
All electromagnetic radiation is light, but we can only see a small portion of this radiation—the portion we call visible light. Close examination of the visible-light spectrum from our Sun and other stars reveals a pattern of dark lines—called absorption lines. These patterns can provide important scientific clues that reveal hidden properties of objects throughout the universe.

16. Ultraviolet image of the Sun X-ray image of the Sun
Since Earth's atmosphere blocks x-ray radiation, telescopes with x-ray detectors must be positioned above Earth's absorbing atmosphere. X-rays come from objects that are millions of degrees Celsius—such as pulsars, galactic supernovae remnants, and the accretion disk of black holes.
Ultraviolet images of galaxies show mainly clouds of gas containing newly formed stars that are many times more massive than the Sun and glow strongly in ultraviolet light. In contrast, visible light images of galaxies show mostly the yellow and red light of older stars. By comparing these types of data, astronomers can learn about the structure and evolution of galaxies.

17. Gamma image of the Sun
Gamma rays have the smallest wavelengths and the most energy of any wave in the electromagnetic spectrum. They are produced by the hottest and most energetic objects in the universe, such as neutron stars and pulsars, supernova explosions, and regions around black holes. If we could see gamma rays, the night sky would look strange and unfamiliar. The familiar view of constantly shining constellations would be replaced by ever-changing bursts of high-energy gamma radiation that last fractions of a second to minutes, popping like cosmic flashbulbs, momentarily dominating the gamma-ray sky and then fading.

18. Images of Crab nebula taken at different wavelengths.

19. Microwaves
Infrared
X-rays
Ultraviolet- (UV)