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Chapter 4

Chapter 4. Stars, Galaxies, and the Universe. Telescopes. To understand how telescopes work, its useful to understand the nature of the electromagnetic radiation. Light is a form of electromagnetic radiation, or energy that can travel through space in the form of waves.

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Chapter 4

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  1. Chapter 4 Stars, Galaxies, and the Universe

  2. Telescopes • To understand how telescopes work, its useful to understand the nature of the electromagnetic radiation. Light is a form of electromagnetic radiation, or energy that can travel through space in the form of waves. • Scientists call the light you can see visible light. • Visible light is just one of the many types of electromagnetic radiation. • The distance between the crest of one wave and the crest of the next wave is known as wavelength. • If you shine white light through a prism, the light spreads out to make a range of different colors with different wavelengths, called a spectrum

  3. Electromagnetic Spectrum • The electromagnetic spectrum includes the entire range of radio waves, infrared radiation, visible light, ultraviolet radiation, X-rays, and gamma rays.

  4. Types of Telescopes • Telescopes are instruments that collect and focus light and other forms of electromagnetic radiation. • The two major types of optical telescopes are refracting and reflecting telescopes. • A refracting telescope uses a convex lenses to gather and focus light. • A reflecting telescope uses a curves mirror to collect and focus light. • Radio telescopes are devices used to detect radio waves from objects in space. • Some telescopes detect infrared radiation, which has longer wavelengths than visible light but shorter wavelengths than radio waves.

  5. Observatories • Many large observatories are located on mountaintops or in space. • One of the best observatory sites on Earth is on the top of Mauna Kea, a dormant volcano on the island of Hawaii.

  6. Telescopes in Space • X-rays, gamma rays, and most ultraviolet radiation are blocked by Earth’s atmosphere. To detect these wavelengths, astronomers have placed telescopes in space. • The Hubble Space telescope is a reflecting telescope and orbits Earth above its atmosphere. • The hottest objects in space give off X-rays. The Chandra X-ray Observatory produces images in the X-ray portion of the spectrum.

  7. Telescopes in Space • X-rays, gamma rays, and most UV radiation are blocked by Earth’s atmosphere. • The Hubble Space Telescope is a reflecting telescope. • The hottest objects in space give off x-rays

  8. Characteristics of Stars • Characteristics used to classify stars include color, temperature, size, composition, and brightness. • Astronomers use the patterns of the constellations to locate objects in the night sky.

  9. Color and Temperature • Like hot objects on Earth, a star’s color reveals its surface temperature. • The hottest stars in the sky, with surface temperatures of over 20,000 degrees Celsius appear bluish.

  10. Size and Chemical Compostion • Most stars are much smaller than the sun. • White dwarfs are about the size of Earth. • Neutron stars are even smaller. • Stars vary in their chemical composition. They are mostly 73 percent hydrogen, 25 percent helium and 2 percent other elements by mass. • A spectrograph is a device that breaks light into colors and produces an image of the resulting spectrum.

  11. Brightness of Stars • The brightness of a star depends upon both size and temperature. • A star’s apparent brightness is its brightness as seen from Earth. • A star’s absolute brightness is the brightness the star would have if it were at a standard distance from Earth.

  12. Measuring Distances to Stars • Astronomers use a unit called the light-year to measure distances between the stars. • A light years is the distance that light travels in one year, about 9.5 million kilometers. • A light year is a unit of distance, not time.

  13. Hertsprung-Russell Diagram • Astronomers use the HR diagrams to classify stars and to understand how stars change over time. • More than 90 percent of stars of all stars, including the sun are main sequence stars.

  14. The Lives of Stars • A star is born when the contracting gases and dust from a nebula become so dense and hot that nuclear fusion starts. • All stars begin their lives as parts of nebulas. • Proto means “earliest” in Greek, so a protostar is the earliest stage of a star’s life. • How long a star lives depends on its mass. • Stars that have more mass than the sun have shorter lifetimes.

  15. Deaths of Stars • After a star runs out of fuel, it becomes a white dwarf, a neutron star, or a black hole • Low mass stars and medium stars like the sun take billions of years to use up their nuclear fuel. • The blue-white core of the star that is left behind cools and becomes a white dwarf. • The life cycle of a high mass star is quite different from the life cycle of a low mass or medium star.

  16. After a supernova, some of the material from the star expands into space. • This material may become part of a nebula. • After a supergiant explodes, some of the material from the star is left behind. This material may form a neutron star. • Spinning neutron stars are called pulsars, short for pulsating radio sources. • Some pulsars spin hundreds of times per second.

  17. Black Hole • The most massive stars – those having more than 40 times the mass of the sun, may become black holes when they die. • A black hole is an object with gravity so strong that nothing, not even light can escape. • No light, radio waves, or any other form of radiation can ever get out of a black hole, so it is not possible to detect a black hole directly.

  18. Star Systems and Clusters • Most stars are members of groups of two or more stars, called a star system. • Star systems that have two or more stars are called double stars or binary stars. • Often one star in a binary star is much brighter and more massive than the other. • A system in which one star periodically blocks the light from another is called an eclipsing binary.

  19. There are two major types of star clusters: open clusters and globular clusters. • Open clusters have a loose, disorganized appearance and contain no more than a few hundred stars. • Globular clusters are large groupings of older stars. They are round and densely packed with stars – some may contain more than a million stars.

  20. Galaxies • Astronomers classify galaxies into the following: Spiral, elliptical, and irregular. • Our solar system is located in a spiral galaxy called the Milky Way. • In 1960s, astronomers discovered objects that are very bright, but also very far away. Many of these objects are 10 billion light-years or more away, making them among the most distant objects in the universe. • These objects were given the name quasi-stellar objects, or quasars.

  21. The Scale of the Universe • Since the numbers astronomers use are often very large or very small, they frequently use scientific notation to describe sizes and distances in the universe. • Scientific notation uses powers of ten to write very large or very small numbers in shorter terms.

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