universe eighth edition
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Roger A. Freedman • William J. Kaufmann III. Universe Eighth Edition. CHAPTER 23 Our Galaxy. Read Chapters 23, 24, 26 and 27 Chapter 23 quiz due Wednesday 12/1 Exam 4 scheduled for Monday 12/13, 5-7 PM. HW. Our solar system is located. near a globular cluster in the halo of our Galaxy. - PowerPoint PPT PresentationTRANSCRIPT
UniverseUniverseEighth EditionEighth Edition
UniverseUniverseEighth EditionEighth Edition
Roger A. Freedman • William J. Kaufmann III
CHAPTER 23CHAPTER 23
Our GalaxyOur Galaxy
CHAPTER 23CHAPTER 23
Our GalaxyOur Galaxy
Read Chapters 23, 24, 26 and 27Read Chapters 23, 24, 26 and 27Chapter 23 quiz due Wednesday 12/1Chapter 23 quiz due Wednesday 12/1
Exam 4 scheduled for Monday 12/13, Exam 4 scheduled for Monday 12/13, 5-7 PM5-7 PM
HW
Our solar system is located
A. near a globular cluster in the halo of our Galaxy.
B. near a globular cluster in a spiral arm of our Galaxy.
C. in a spiral arm of our Galaxy.
D. in the nucleus of our Galaxy.
E. in the disk of our Galaxy, but not within a spiral arm.
Q23.5
Our solar system is located
A. near a globular cluster in the halo of our Galaxy.
B. near a globular cluster in a spiral arm of our Galaxy.
C. in a spiral arm of our Galaxy.
D. in the nucleus of our Galaxy.
E. in the disk of our Galaxy, but not within a spiral arm.
A23.5
Most astronomers think that there is dark matter in our Galaxy because
A. stars in the outer edges of our Galaxy move faster than expected.
B. stars in the outer edges of our Galaxy move slower than expected.
C. large amounts of matter can be seen at infrared wavelengths.
D. large amounts of matter can be seen at radio wavelengths.
E. large amounts of matter can be seen at x-ray wavelengths.
Q23.9
Most astronomers think that there is dark matter in our Galaxy because
A. stars in the outer edges of our Galaxy move faster than expected.
B. stars in the outer edges of our Galaxy move slower than expected.
C. large amounts of matter can be seen at infrared wavelengths.
D. large amounts of matter can be seen at radio wavelengths.
E. large amounts of matter can be seen at x-ray wavelengths.
A23.9
Key Ideas The Shape and Size of the Galaxy:The Shape and Size of the Galaxy: Our Galaxy has a Our Galaxy has a
disk about 50 kpc (160,000 ly) in diameter and about 600 disk about 50 kpc (160,000 ly) in diameter and about 600 pc (2000 ly) thick, with a high concentration of interstellar pc (2000 ly) thick, with a high concentration of interstellar dust and gas in the disk.dust and gas in the disk.
The galactic center is surrounded by a large distribution of The galactic center is surrounded by a large distribution of stars called the central bulge. This bulge is not perfectly stars called the central bulge. This bulge is not perfectly symmetrical, but may have a bar or peanut shape.symmetrical, but may have a bar or peanut shape.
The disk of the Galaxy is surrounded by a spherical The disk of the Galaxy is surrounded by a spherical distribution of globular clusters and old stars, called the distribution of globular clusters and old stars, called the galactic halo.galactic halo.
There are about 200 billion (2 There are about 200 billion (2 10 101111) stars in the Galaxy’s ) stars in the Galaxy’s disk, central bulge, and halo.disk, central bulge, and halo.
Key Ideas The Sun’s Location in the Galaxy:The Sun’s Location in the Galaxy: Our Sun lies within Our Sun lies within
the galactic disk, some 8000 pc (26,000 ly) from the the galactic disk, some 8000 pc (26,000 ly) from the center of the Galaxy.center of the Galaxy.
Interstellar dust obscures our view at visible wavelengths Interstellar dust obscures our view at visible wavelengths along lines of sight that lie in the plane of the galactic along lines of sight that lie in the plane of the galactic disk. As a result, the Sun’s location in the Galaxy was disk. As a result, the Sun’s location in the Galaxy was unknown for many years.unknown for many years.
This dilemma was resolved by observing parts of the This dilemma was resolved by observing parts of the Galaxy outside the disk.Galaxy outside the disk.
The Sun orbits around the center of the Galaxy at a The Sun orbits around the center of the Galaxy at a speed of about 790,000 km/h. It takes about 220 million speed of about 790,000 km/h. It takes about 220 million years to complete one orbit.years to complete one orbit.
Key Ideas The Rotation of the Galaxy and Dark Matter:The Rotation of the Galaxy and Dark Matter: From From
studies of the rotation of the Galaxy, astronomers studies of the rotation of the Galaxy, astronomers estimate that the total mass of the Galaxy is about 10estimate that the total mass of the Galaxy is about 101212 MM. Only about 10% of this mass is in the form of visible . Only about 10% of this mass is in the form of visible
stars, gas, and dust. The remaining 90% is in some stars, gas, and dust. The remaining 90% is in some nonvisible form, called dark matter, that extends beyond nonvisible form, called dark matter, that extends beyond the edge of the luminous material in the Galaxy.the edge of the luminous material in the Galaxy.
Our Galaxy’s dark matter may be a combination of Our Galaxy’s dark matter may be a combination of MACHOs (dim, star-sized objects), massive neutrinos, MACHOs (dim, star-sized objects), massive neutrinos, and WIMPs (relatively massive subatomic particles).and WIMPs (relatively massive subatomic particles).
Key Ideas The Galaxy’s Spiral Structure:The Galaxy’s Spiral Structure: OB associations, H II OB associations, H II
regions, and molecular clouds in the galactic disk outline regions, and molecular clouds in the galactic disk outline huge spiral arms.huge spiral arms.
Spiral arms can be traced from the positions of clouds of Spiral arms can be traced from the positions of clouds of atomic hydrogen. These can be detected throughout the atomic hydrogen. These can be detected throughout the galactic disk by the 21-cm radio waves emitted by the galactic disk by the 21-cm radio waves emitted by the spin-flip transition in hydrogen. These emissions easily spin-flip transition in hydrogen. These emissions easily penetrate the intervening interstellar dust.penetrate the intervening interstellar dust.
Key Ideas Theories of Spiral Structure:Theories of Spiral Structure: There are two leading There are two leading
theories of spiral structure in galaxies.theories of spiral structure in galaxies. According to the density-wave theory, spiral arms are According to the density-wave theory, spiral arms are
created by density waves that sweep around the Galaxy. created by density waves that sweep around the Galaxy. The gravitational field of this spiral pattern compresses the The gravitational field of this spiral pattern compresses the interstellar clouds through which it passes, thereby interstellar clouds through which it passes, thereby triggering the formation of the OB associations and H II triggering the formation of the OB associations and H II regions that illuminate the spiral arms.regions that illuminate the spiral arms.
According to the theory of self-propagating star formation, According to the theory of self-propagating star formation, spiral arms are caused by the birth of stars over an spiral arms are caused by the birth of stars over an extended region in a galaxy. Differential rotation of the extended region in a galaxy. Differential rotation of the galaxy stretches the star-forming region into an elongated galaxy stretches the star-forming region into an elongated arch of stars and nebulae.arch of stars and nebulae.
Key Ideas The Galactic Nucleus:The Galactic Nucleus: The innermost part of the The innermost part of the
Galaxy, or galactic nucleus, has been studied through its Galaxy, or galactic nucleus, has been studied through its radio, infrared, and X-ray emissions (which are able to radio, infrared, and X-ray emissions (which are able to pass through interstellar dust).pass through interstellar dust).
A strong radio source called Sagittarius A* is located at A strong radio source called Sagittarius A* is located at the galactic center. This marks the position of a the galactic center. This marks the position of a supermassive black hole with a mass of about 3.7 supermassive black hole with a mass of about 3.7 101066 MM..