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Stars

Pgs. 98 - 104. Stars. Color of Stars. Most stars look like faint dots of light in the night sky but are actually huge balls of burning gas. Believe it or not gases will burn at different colors. The color helps determine the temperature. Betelgeuse is a red star and

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Stars

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  1. Pgs. 98 - 104 Stars

  2. Color of Stars • Most stars look like faint dots of light in the night sky but are actually huge balls of burning gas. • Believe it or not gases will burn at different colors. • The color helps determine the temperature. • Betelgeuse is a red star and Rigel is a blue star.

  3. Composition of Stars • If you look at white light through a glass prism, you see a rainbow of colors called a spectrum. • The spectrum contains all the colors we see. • A hot solid object like the glowing wire of a light bulb gives off a continuous spectrum. • Astronomers use a tool called a spectrograph to spread starlight out into its colors. • Since stars are not solid objects they do not give off a continuous spectrum.

  4. Hot Dense Gas • Stars are made of gases that are so dense that they act like a hot solid. • The “surface” of a star, the part we see, gives off a continuous spectrum. • The light we see has to pass through the star’s atmosphere and Earth’s atmosphere as well. • The star produces a spectrum with lines in it.

  5. Making an ID • Restaurants use neon signs to attract customers. • The neon sign glows when there is an electric current going through it. • Using a spectrograph, we would see emission lines, that are made when certain wavelengths are given off by hot gases. • Each gas has its own set of emission lines that give the gas an identity through a spectrograph.

  6. Spectrograph of Gases

  7. Trapping the Light • The spectrum produced by a star is not continuous, nor is it bright lines. • The star’s atmosphere is cooler than the star itself and the gases absorb some of the star’s light. • This removes some colors of light from the continuous spectrum of a hot star.

  8. Cosmic Detective Work • If light from a hot solid passes through a cooler gas it produces absorption spectrum. • This is a continuous spectrum with dark lines where less light gets through. • The pattern of lines shows some of the elements that are in the stars atmosphere. • Since there are several elements making up a star, it can be a puzzle to figure out its parts.

  9. Classifying Stars – Differences in Temperature • Stars are now classified by how hot they are. • We can see temperature differences as colors. • The hottest stars are blue and designated as letter ‘O’. • The order of stars are classified as OBAFGKM.

  10. Differences in Brightness • Ancient astronomers classified stars by their brightness using only their eyes. • The brightest stars were first magnitude stars and the faintest were sixth magnitude stars. • Once telescopes were developed, we were able to see more stars than ever before. • Scientists added to the old system using positive numbers for dim stars and negative numbers for bright stars. • Examples: a telescope can see 29th magnitude star and Sirius (the brightest in the night sky) is a -1.4 magnitude star.

  11. Apparent Magnitude • How bright a light looks, or appears, is called apparent magnitude. • If you look at a row of street lights, the closest to you appears brightest. • As they get farther away from you, their brightness will decrease by the square of their distance. • A light 10m away will appear 4 times as bright as one 20m away.

  12. Absolute Magnitude • The actual brightness of a star is absolute magnitude. • Scientists use the star’s apparent magnitude and its distance from Earth to calculate absolute magnitude. • If all stars were the same distance away, then a star’s absolute and apparent magnitude would be the same. • The sun has an absolute magnitude of 4.8 and an apparent magnitude of -26.8.

  13. Distance to the Stars • Astronomers use light-years to describe distances between stars. • A light-year is the distance light travels in one year (9.5 trillion kilometers/ year). • The North Star is 431 light-years. • More distant stars appear to move as the Earth rotates. • This shift is called a parallax.

  14. Motions of Stars • The Earth rotates on its axis and different parts of its surface face the sun just as the Earth revolves around the sun. • At different parts of the year, we see different stars in the night sky. • At night, different parts of the Earth will face different parts of the universe.

  15. Apparent Motion • If you look at the night sky long enough, the stars appear to move across the sky. • The stars will actually appear to move around the North Star, Polaris. • This motion is caused by the Earth’s rotation on its axis. • The North Star aligns with the Earth’s poles and rotational direction. • The other stars will make a circle around the North Star every 24 hours, called circumpolar stars

  16. Actual Motion • Each star in outer space is actually moving. • Since stars are so distant, their real motion is hard to observe. • Over thousands of years, the stars’ patterns in the sky will change over time.

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