Prentice Hall EARTH SCIENCE

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Presentation transcript:

Prentice Hall EARTH SCIENCE Tarbuck Lutgens 

Chapter 25 Beyond Our Solar System Who is Stan Hatfield and Ken Pinzke

25.1 Properties of Stars Characteristics of Stars A constellation is an apparent group of stars originally named for mythical characters. The sky contains 88 constellations.  Star Color and Temperature • Color is a clue to a star’s temperature.

The Constellation Orion Makes no sense without caption in book

25.1 Properties of Stars Characteristics of Stars  Binary Stars and Stellar Mass • A binary star is one of two stars revolving around a common center of mass under their mutual gravitational attraction. • Binary stars are used to determine the star property most difficult to calculate—its mass.

Common Center of Mass Makes no sense without caption in book

25.1 Properties of Stars Measuring Distances to Stars  Parallax • Parallax is the slight shifting of the apparent position of a star due to the orbital motion of Earth. • The nearest stars have the largest parallax angles, while those of distant stars are too small to measure.  Light-Year • A light-year is the distance light travels in a year, about 9.5 trillion kilometers.

Photo taken 6 months later Parallax Original Photo Photo taken 6 months later Makes no sense without caption in book

25.1 Properties of Stars Stellar Brightness  Apparent Magnitude • Apparent magnitude is the brightness of a star when viewed from Earth. • Three factors control the apparent brightness of a star as seen from Earth: how big it is, how hot it is, and how far away it is.  Absolute Magnitude • Absolute magnitude is the apparent brightness of a star if it were viewed from a distance of 32.6 light-years.

Distance, Apparent Magnitude, and Absolute Magnitude of Some Stars Makes no sense without caption in book

25.1 Properties of Stars Hertzsprung–Russell Diagram  A Hertzsprung–Russell diagram shows the relationship between the absolute magnitude and temperature of stars.  A main-sequence star is a star that falls into the main sequence category on the H–R diagram. This category contains the majority of stars and runs diagonally from the upper left to the lower right on the H–R diagram.

Hertzsprung–Russell Diagram Makes no sense without caption in book

25.1 Properties of Stars Hertzsprung–Russell Diagram  A red giant is a large, cool star of high luminosity; it occupies the upper-right portion of the H–R diagram.  A supergiant is a very large, very bright red giant star.

25.1 Properties of Stars Hertzsprung–Russell Diagram  Variable Stars • A Cepheid variable is a star whose brightness varies periodically because it expands and contracts; it is a type of pulsating star. • A nova is a star that explosively increases in brightness.

Images of a Nova Taken Two Months Apart Makes no sense without caption in book

25.1 Properties of Stars Hertzsprung–Russell Diagram  Interstellar Matter • A nebula is a cloud of gas and/or dust in space. • There are two major types of nebulae: 1. Bright nebula - Emission nebula - Reflection nebula 2. Dark nebula

Interstellar Matter Makes no sense without caption in book

25.2 Stellar Evolution Star Birth  Protostar Stage • A protostar is a collapsing cloud of gas and dust destined to become a star—a developing star not yet hot enough to engage in nuclear fusion. • When the core of a protostar has reached about 10 million K, pressure within is so great that nuclear fusion of hydrogen begins, and a star is born.

Nebula, Birthplace of Stars Makes no sense without caption in book

Balanced Forces Makes no sense without caption in book

25.2 Stellar Evolution Star Birth  Main-Sequence Stage • Stars age at different rates. - Massive stars use fuel faster and exist for only a few million years. - Small stars use fuel slowly and exist for perhaps hundreds of billions of years. • A star spends 90 percent of its life in the main-sequence stage.

25.2 Stellar Evolution Star Birth  Red-Giant Stage • Hydrogen burning migrates outward. The star’s outer envelope expands. • Its surface cools and becomes red. • The core collapses as helium is converted to carbon. Eventually all nuclear fuel is used and gravity squeezes the star.

25.2 Stellar Evolution Burnout and Death  All stars, regardless of their size, eventually run out of fuel and collapse due to gravity.  Death of Low-Mass Stars • Stars less than one-half the mass of the sun never evolve to the red giant stage but remain in the stable main-sequence stage until they consume all their hydrogen fuel and collapse into a white dwarf.

25.2 Stellar Evolution Burnout and Death  Death of Medium-Mass Stars • Stars with masses similar to the sun evolve in essentially the same way as low-mass stars. • During their collapse from red giants to white dwarfs, medium-mass stars are thought to cast off their bloated outer layer, creating an expanding round cloud of gas called planetary nebula.

Planetary Nebula Makes no sense without caption in book

25.2 Stellar Evolution Burnout and Death  Death of Massive Stars • In contrast to sunlike stars, stars that are over three times the sun’s mass have relatively short life spans, which end in a supernova event. A supernova is an exploding massive star that increases in brightness many thousands of times. The massive star’s interior condenses and may produce a hot, dense object that is either a neutron star or a black hole.

Crab Nebula in the Constellation Taurus Makes no sense without caption in book

Stellar Evolution Makes no sense without caption in book

25.2 Stellar Evolution Burnout and Death  H–R Diagrams and Stellar Evolution • Hertzsprung–Russell diagrams have been helpful in formulating and testing models of stellar evolution. • They are also useful for illustrating the changes that take place in an individual star during its life span.

Life Cycle of a Sunlike Star Makes no sense without caption in book

25.2 Stellar Evolution Stellar Remnants  White Dwarfs • A white dwarf is a star that has exhausted most or all of its nuclear fuel and has collapsed to a very small size, believed to be near its final stage of evolution. • The sun begins as a nebula, spends much of its life as a main-sequence star, and then becomes a red giant, a planetary nebula, a white dwarf, and, finally, a black dwarf.

Summary of Evolution for Stars of Various Masses Makes no sense without caption in book

25.2 Stellar Evolution Stellar Remnants  Neutron Stars  Supernovae • A neutron star is a star of extremely high density composed entirely of neutrons. • Neutron stars are thought to be remnants of supernova events.  Supernovae • A pulsar is a source that radiates short bursts or pulses of radio energy in very regular periods. • A pulsar found in the Crab Nebula during the 1970s is undoubtedly the remains of the supernova of 1054.

Veil Nebula in the Constellation Cygnus Makes no sense without caption in book

25.2 Stellar Evolution Stellar Remnants  Black Holes • A black hole is a massive star that has collapsed to such a small volume that its gravity prevents the escape of everything, including light. Scientists think that as matter is pulled into a black hole, it should become very hot and emit a flood of X-rays before being pulled in.

Black Hole Makes no sense without caption in book

25.3 The Universe The Milky Way Galaxy  A galaxy is a group of stars, dust, and gases held together by gravity.  Size of the Milky Way • The Milky Way is a large spiral galaxy whose disk is about 100,000 light-years wide and about 10,000 light-years thick at the nucleus.  Structure of the Milky Way • Radio telescopes reveal that the Milky Way has at least three distinct spiral arms, with some splintering.

Structure of the Milky Way Makes no sense without caption in book

25.3 The Universe Types of Galaxies  Spiral Galaxies • About 30 percent of all galaxies are spiral galaxies. • They have large diameters of 20,000 to 125,000 light-years and contain both young and old stars.  Elliptical Galaxies • About 60 percent of galaxies are classified as elliptical galaxies. • Elliptical galaxies range in shape from round to oval.

Spiral Galaxies Makes no sense without caption in book

Elliptical Galaxy Makes no sense without caption in book

25.3 The Universe Types of Galaxies  Irregular Galaxies • Only 10 percent of the known galaxies have irregular shapes and are classified as irregular galaxies. • In addition to shape and size, one of the major differences among different types of galaxies is the age of their stars. Irregular galaxies contain young stars.  Galaxy Clusters • A galaxy cluster is a system of galaxies containing several to thousands of member galaxies.

Irregular Galaxy Makes no sense without caption in book

Galaxy Cluster Makes no sense without caption in book

25.3 The Universe The Expanding Universe  Red Shifts  Hubble’s Law • Red shift, or a Doppler shift toward the red end of the spectrum, occurs because the light waves are “stretched,” which shows that Earth and the source are moving away from each other.  Hubble’s Law • Hubble’s law is a law that states that the galaxies are retreating from the Milky Way at a speed that is proportional to their distance. • The red shifts of distant galaxies indicate that the universe is expanding.

25.3 The Universe The Expanding Universe  Hubble’s Law • To help visualize the nature of the universe, imagine a loaf of raisin bread dough that has been set out to rise for a few hours. As the dough doubles in size, so does the distance between all the raisins. Those objects located father apart move away from each other more rapidly.

Raisin Bread Dough Analogy Makes no sense without caption in book

25.3 The Universe The Big Bang  The big bang theory states that at one time, the entire universe was confined to a dense, hot, supermassive ball. Then, about 13.7 billion years ago, a violent explosion occurred, hurling this material in all directions.

The Big Bang Makes no sense without caption in book

25.3 The Universe The Big Bang  Supporting Evidence • The red shift of galaxies supports the big bang and the expanding universe theories. • Scientists discovered a type of energy called cosmic background radiation. Scientists think that this radiation was produced during the big bang.

25.3 The Universe The Big Bang  The Big Crunch? • The future of the universe follows two possible paths: 1. The universe will expand forever. 2. The outward expansion will stop and gravitational contraction will follow. • The view currently favored by most scientists is an expanding universe with no ending point. • It should be noted, however, that the methods used to determine the ultimate fate of the universe have substantial uncertainties.