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Section 2: Measuring the Stars

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1 Section 2: Measuring the Stars
Stellar classification is based on measurement of light spectra, temperature, and composition. K What I Know W What I Want to Find Out L What I Learned

2 Essential Questions How are distances between stars measured?
What is the difference between brightness and luminosity? What are the properties used to classify stars? Measuring the Stars Copyright © McGraw-Hill Education

3 Vocabulary Review New wavelength constellation binary star parsec
parallax apparent magnitude absolute magnitude luminosity Hertzsprung-Russell diagram main sequence Measuring the Stars Copyright © McGraw-Hill Education

4 Patterns of Stars Long ago, many civilizations looked at the brightest stars and named groups of them after animals, mythological characters, or everyday objects. These groups of stars are called constellations. Today, astronomers group stars by the 88 constellations named by ancient peoples. Copyright © McGraw-Hill Education Measuring the Stars

5 Patterns of Stars Some constellations are visible throughout the year, depending on the observer’s location. Constellations that appear to rotate around one of the poles are called circumpolar constellations. Ursa Major, which contains the Big Dipper, is a circumpolar constellation for most of the northern hemisphere. Copyright © McGraw-Hill Education Measuring the Stars

6 Patterns of Stars Unlike circumpolar constellations, the other constellations can be seen only at certain times of the year because of Earth’s changing position in its orbit around the Sun. Copyright © McGraw-Hill Education Measuring the Stars

7 Patterns of Stars The most familiar constellations are the ones that are part of the zodiac. These twelve constellations can be seen in both the northern and southern hemispheres. Copyright © McGraw-Hill Education Measuring the Stars

8 Patterns of Stars Star clusters
By measuring distances to stars and observing how their gravities interact with each other, scientists can determine which stars are gravitationally bound to each other. A group of stars that are gravitationally bound to each other is called a cluster. Copyright © McGraw-Hill Education Measuring the Stars

9 Patterns of Stars Star clusters
An open cluster is a group of stars that are not densely packed. A globular cluster is a group of stars that are densely packed into a spherical shape. Copyright © McGraw-Hill Education Measuring the Stars

10 Patterns of Stars Binaries
When only two stars are gravitationally bound together and orbit a common center of mass, they are called binary stars. More than half of the stars in the sky are either binary stars or members of multiple-star systems. Copyright © McGraw-Hill Education Measuring the Stars

11 Patterns of Stars Binaries
Most binary stars appear to be single stars to the human eye, even with a telescope. The two stars are usually too close together to appear separately, and one of the two is often much brighter than the other. Copyright © McGraw-Hill Education Measuring the Stars

12 Visualizing Star Groupings
When you look into the night sky, the stars seem to be randomly spaced from horizon to horizon. Upon closer inspection, you begin to see groups of stars that seem to cluster in one area. Copyright © McGraw-Hill Education Measuring the Stars

13 Add link to Animation from p. 839 here.
Visualizing Star Groupings Concepts In Motion FPO Add link to Animation from p. 839 here. Measuring the Stars Copyright © McGraw-Hill Education

14 Patterns of Stars Doppler shifts
The most common way to tell that a star is one of a binary pair is to find subtle wavelength shifts, called Doppler shifts. Scientists use Doppler shifts to determine the speed and direction of a star’s motion. Copyright © McGraw-Hill Education Measuring the Stars

15 Patterns of Stars Doppler shifts
When a star moves toward the observer, the light emitted by the star shifts toward the blue end of the electromagnetic spectrum. When a star moves away from the observer, its light shifts toward the red. Copyright © McGraw-Hill Education Measuring the Stars

16 Add link to Animation from p. 840 here.
The Doppler Effect Concepts In Motion FPO Add link to Animation from p. 840 here. Measuring the Stars Copyright © McGraw-Hill Education

17 Stellar Positions and Distances
Astronomers use two units of measure for long distances. One is the light-year (ly). A light-year is the distance that light travels in one year, equal to × 1012 km. Astronomers often use a unit larger than a light-year—a parsec (pc), which is equal to 3.26 ly, or × 1013 km. Copyright © McGraw-Hill Education Measuring the Stars

18 Stellar Positions and Distances
Parallax When estimating the distance of stars from Earth, astronomers must account for the fact that nearby stars shift in position as observed from Earth. This apparent shift in position caused by the motion of the observer is called parallax. Copyright © McGraw-Hill Education Measuring the Stars

19 Add link to Animation from p. 841 here.
Parallax Concepts In Motion FPO Add link to Animation from p. 841 here. Measuring the Stars Copyright © McGraw-Hill Education

20 Stellar Positions and Distances
Parallax The distance to a star can be estimated from its parallax shift by measuring the angle of the change. With advancements in technology, such as the Hipparcos satellite, astronomers can find accurate distances up to 100 pc by using the parallax technique. Copyright © McGraw-Hill Education Measuring the Stars

21 Basic Properties of Stars
The basic properties of a star are mass, diameter, and luminosity, which are all related to each other. Temperature is another property and is estimated by finding the spectral type of a star. Copyright © McGraw-Hill Education Measuring the Stars

22 Basic Properties of Stars
Temperature controls the nuclear reaction rate and governs the luminosity, or absolute magnitude. Apparent magnitude is how bright the stars and planets appear in the sky from Earth. Copyright © McGraw-Hill Education Measuring the Stars

23 Basic Properties of Stars
Magnitude Absolute magnitude is how bright a star would appear if it were placed at a distance of 10 pc. The absolute magnitude compared to the apparent magnitude is used to find the distance to a star. Copyright © McGraw-Hill Education Measuring the Stars

24 Basic Properties of Stars
Magnitude The classification of stars by absolute magnitude allows comparisons that are based on how bright the stars would appear at equal distances from an observer. The disadvantage of absolute magnitude is that it can be difficult to determine unless the actual distance to a star is known. Copyright © McGraw-Hill Education Measuring the Stars

25 Basic Properties of Stars
Magnitude Apparent magnitudes do not give an actual measure of energy output. To measure the energy output from the surface of a star per second, called its power or luminosity, an astronomer must know both the star’s apparent magnitude and how far away it is. Copyright © McGraw-Hill Education Measuring the Stars

26 Basic Properties of Stars
Magnitude Luminosity is measured in units of energy emitted per second, or watts. The Sun’s luminosity is about 3.85 × 1026 W. The values for other stars vary widely, from about to more than 1 million times the Sun’s luminosity. No other stellar property varies as much. Copyright © McGraw-Hill Education Measuring the Stars

27 Classification of Stars
Temperature Stars are assigned spectral types in the following order: O, B, A, F, G, K, and M. Each class is subdivided into more specific divisions with numbers from 0 to 9. Copyright © McGraw-Hill Education Measuring the Stars

28 Classification of Stars
Temperature The classes were originally based only on the pattern of spectral lines, but astronomers later discovered that the classes also correspond to stellar temperatures, with the O stars being the hottest and the M stars being the coolest. Thus, by examination of a star’s spectrum, it is possible to estimate its temperature. Copyright © McGraw-Hill Education Measuring the Stars

29 Classification of Stars
Temperature Temperature is also related to luminosity and absolute magnitude. Hotter stars put out more light than stars with lower temperatures. Distance can be determined by calculating a star’s luminosity based on its temperature. Copyright © McGraw-Hill Education Measuring the Stars

30 Classification of Stars
Composition All stars, including the Sun, have nearly identical compositions, despite differences in their spectra. The differences in the appearance of their spectra are almost entirely a result of temperature differences. Typically, about 73 percent of a star’s mass is hydrogen, about 25 percent is helium, and the remaining 2 percent is composed of all the other elements. Copyright © McGraw-Hill Education Measuring the Stars

31 Classification of Stars
H-R diagrams A Hertzsprung-Russell diagram (H-R diagram) is a graph that relates stellar characteristics— class, mass, temperature, diameter, and luminosity. Absolute magnitude is plotted on the vertical axis and temperature or spectral type is plotted on the horizontal axis. Copyright © McGraw-Hill Education Measuring the Stars

32 Add link to Interactive Table from p. 844 here.
Relationships of Spectral Types of Stars Concepts In Motion FPO Add link to Interactive Table from p. 844 here. Measuring the Stars Copyright © McGraw-Hill Education

33 Classification of Stars
H-R diagrams Most stars occupy the region in the diagram called the main sequence, which runs diagonally from the upper-left corner, where hot, luminous stars are represented, to the lower-right corner, where cool, dim stars are represented. Copyright © McGraw-Hill Education Measuring the Stars

34 Add link to Interactive Table from p. 845 here.
Properties of Main-Sequence Stars Concepts In Motion FPO Add link to Interactive Table from p. 845 here. Measuring the Stars Copyright © McGraw-Hill Education

35 Classification of Stars
Main sequence While stars are in the main sequence, they are fusing hydrogen in their cores. As stars evolve off the main sequence, they begin to fuse helium in their cores and burn hydrogen around the core edges. A star’s mass determines almost all its other properties, including its main-sequence lifetime. The more massive a star is, the higher its central temperature and the more rapidly it burns its hydrogen fuel. Copyright © McGraw-Hill Education Measuring the Stars

36 Classification of Stars
Main sequence Red giants are large, cool, luminous stars. They are so large—more than 100 times the size of the Sun in some cases—that Earth would be swallowed up if the Sun were to become a red giant. Small, dim, hot stars are called white dwarfs. A white dwarf is about the size of Earth but has a mass about as large as the Sun’s. Copyright © McGraw-Hill Education Measuring the Stars

37 Review Essential Questions Vocabulary
How are distances between stars measured? What is the difference between brightness and luminosity? What are the properties used to classify stars? Vocabulary constellation binary star parsec parallax apparent magnitude absolute magnitude luminosity Hertzsprung-Russell diagram main sequence Measuring the Stars Copyright © McGraw-Hill Education


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