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The Electromagnetic Spectrum

The Electromagnetic Spectrum. Radio, microwaves , infrared, visible light, ultraviolet, x-ray , gamma. The Electromagnetic Spectrum. It is natural to think of light as visible light - the light we see with our eyes. However, this is only one type of light.

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The Electromagnetic Spectrum

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  1. The Electromagnetic Spectrum • Radio, microwaves, infrared, visible light, ultraviolet, x-ray, gamma

  2. The Electromagnetic Spectrum • It is natural to think of light as visible light - the light we see with our eyes. However, this is only one type of light. • The entire range of light, which includes the rainbow of colors we normally see, is called the electromagnetic spectrum. • The electromagnetic spectrum includes gamma rays, X-rays, ultraviolet, visible, infrared, microwaves, and radio waves.

  3. The Electromagnetic Spectrum • The only difference between these different types of radiation is their characteristic wavelength or frequency. • Wavelength increases and frequency decreases from gamma rays to radio waves. • All of these forms of radiation travel at the speed of light, which is about 300,000 km/sec.

  4. Electromagnetic Spectrum By studying the Universe across the spectrum we can get a more complete understanding of objects in space. The light from each part of the electromagnetic spectrum brings us valuable and unique information. X-ray image showing hot gas near the center of our Milky Way Galaxy (CXO). infrared view of glowing dust near the center of our Galaxy (2MASS). Visible light image showing stars of different colors.  Ultraviolet view of hot white dwarf stars in a nearby galaxy (ASTRO-1). Radio image of a supernova remnant (NRAO). 

  5. X-Rays and Gamma Rays • High-energy radiation like X-rays and gamma rays are absorbed by our atmosphere, so observatories must be sent into space to study the Universe at these wavelengths. • X-rays and gamma rays are produced by matter which is heated to millions of degrees and are often caused by cosmic explosions, high speed collisions, or by material moving at extremely high speeds. Fermi Gamma-ray Space Telescope CHANDRA X-Ray Telescope

  6. X-Rays and Gamma Rays • X-ray and gamma-ray astronomy has led to the discovery of black holes in space, and has added much to our understanding of supernovae, white dwarfs and pulsars. • High-energy observations also allow us to study the hottest regions of the Sun's atmosphere. X Ray Gamma Ray

  7. X-Rays and Gamma Rays Our Sun in X-Ray Light

  8. Ultraviolet • Most of the ultraviolet light reaching the Earth is blocked by our atmosphere's ozone layer and is very difficult to observe from the ground. • To study light in this region of the spectrum astronomers use high-altitude balloons, rockets, and orbiting observatories. • At ultraviolet wavelengths, most stars fade from view because they are too cool to emit such high energy light. But very young massive stars, some very old stars, bright nebulae, white dwarfs stars, active galaxies and quasars shine brightly in the ultraviolet. Hopkins Ultraviolet Telescope

  9. Ultraviolet • Ultraviolet observations have contributed to our understanding of the Sun's atmosphere and tell us about the composition and temperatures of hot, young stars. • Light from this part of the spectrum also gives astronomers information about the chemical composition, densities, and temperatures of interstellar gas and dust. • Discoveries have included the existence of a hot gaseous halo surrounding our own galaxy. The ultraviolet image shows additional regions of activity deeper in the Sun's atmosphere. The Sun in UV light. The Milky Way in UV light.

  10. Visible • The visible light from space can be detected by ground-based observatories during clear sky evenings. • Visible light observations have given us the most detailed views of our solar system, and have brought us fantastic images of nebulae and galaxies. Hubble Space Telescope

  11. Visible • Although visible light does make it through our atmosphere, it is also very valuable to send optical telescopes and cameras into space. • In the darkness of space we can get a much clearer view of the cosmos. • We can also learn much more about objects in our solar system by viewing them up close using space probes. Milky Way in Visible Light Sun in Visible Light

  12. Infrared • Only a few narrow bands of infrared light can be observed by ground-based observatories. To view the rest of the infrared universe we need to use space based observatories or high-flying aircraft. • Infrared is primarily heat radiation and special detectors cooled to extremely low temperatures are needed for most infrared observations. The Space Infrared Telescope Facility

  13. Infrared • Since infrared can penetrate thick regions of dust in space, infrared observations are used to peer into star-forming regions and into the central areas of our galaxy. • Cool stars and cold interstellar clouds which are invisible in optical light are also observed in the infrared. Infrared Image of the Sun Infrared Image of the Milky Way

  14. Microwaves • Microwaves are used to learn about stars that are behind clouds of dust, galaxy formation and evolution, star and planetary system births, and collect data on Cosmic Background Radiation. The image is a Cosmic Background Explorer (COBE) image of the cosmic microwave background, the pink and blue colors showing the tiny fluctuations in it.This radiation, which fills the entire Universe, is believed to be a clue to the Big Bang.

  15. Radio • Radio waves are very long compared to waves from the rest of the spectrum. Most radio radiation reaches the ground and can be detected during the day as well as during the night. • Radio telescopes use a large metal dish to help detect radio waves.

  16. Radio • . The study of the radio universe brought us the first detection of the radiation left over from the Big Bang. • Radio waves also bring us information about supernovae, quasars, pulsars, regions of gas between the stars, and interstellar molecules. Radio Image of the Milky Way Radio Image of the Sun

  17. Orion (the Hunter) may be a familiar constellation in the winter night sky, but these dramatically different images at various wavelengths are anything but familiar! • The X-ray photograph reveals Sun-like stars, white dwarf stars, neutron stars, and supernova remnants in our own Galaxy, and (in the background) nearby galaxies, clusters of galaxies, and distant quasars. • The ultraviolet image is a close-up view of the belt/sword region of Orion, including the famous Orion Nebula, and is dominated by emission from hot, young stars. • The visible light image shows stars of all ages and temperatures. • In the infrared, our view of Orion is dominated by emission from clouds of dust and gas, the materials from which new stars will be born. • The radio image maps the distribution of hydrogen molecules in the interstellar medium, with red showing the areas of highest concentration. Ultraviolet (MSX) Infrared (IRAS) Visible (AkiriFujii/JPL) Radio (NRAO) X-Ray (ROSAT)

  18. Radio • Ultraviolet • Gamma Rays • Infrared • Microwaves • X-Ray • Visible

  19. Used to learn about the Evolution and Structure of the Universe. • Used to see surface features of space objects • Used to study the beginning of the Universe • Used to see things that can’t be seen in visible light. • Used to find out what a star is made of and its structure. • Used to study the evolution and structure of galaxies. • Used to see stars that are behind clouds of dust.

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