22.3 Checking Out the Theory

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Chapter 22 Stars from Adolescence to Old Age

22.3 Checking Out the Theory

Learning Objectives

By the end of this section, you will be able to:

Explain how the H–R diagram of a star cluster can be related to the cluster’s age and the stages of evolution of its stellar members
Describe how the main-sequence turnoff of a cluster reveals its age

In the previous section, we indicated that that open clusters are younger than globular clusters, and associations are typically even younger. In this section, we will show how we determine the ages of these star clusters. The key observation is that the stars in these different types of clusters are found in different places in the H–R diagram, and we can use their locations in the diagram in combination with theoretical calculations to estimate how long they have lived.

H–R Diagrams of Young Clusters

What does theory predict for the H–R diagram of a cluster whose stars have recently condensed from an interstellar cloud? Remember that at every stage of evolution, massive stars evolve more quickly than their lower-mass counterparts. After a few million years (“recently” for astronomers), the most massive stars should have completed their contraction phase and be on the main sequence, while the less massive ones should be off to the right, still on their way to the main sequence. These ideas are illustrated in [link], which shows the H–R diagram calculated by R. Kippenhahn and his associates at Munich University for a hypothetical cluster with an age of 3 million years.

Hypothetical H-R Diagram of a Young Cluster. In this plot titled “M 2001 Age: 3 million years,” the vertical axis is labeled “Luminosity (LSun),” and goes from 0.1 at the bottom to 100,000 at the top. The horizontal axis is labeled “Surface Temperature (K)”, and goes from 40,000 on the left to 3,000 on the right. The zero-age main sequence is drawn as a red diagonal line starting just above 100,000 LSun at the top of the graph down to about 4000 K at the bottom. The “Present position of Sun” is indicated at 5500 K and 1 LSun. Over-plotted on the graph are black dots representing the individual stars in the cluster. About half of the dots lie neatly along the red line until about 10000 K and 100 LSun. At this point, the remainder of the dots lie above the red line, meaning these stars have yet to reach the main sequence. — **Figure 1.** We see an H–R diagram for a hypothetical young cluster with an age of 3 million years. Note that the high-mass (high-luminosity) stars have already arrived at the main-sequence stage of their lives, while the lower-mass (lower-luminosity) stars are still contracting toward the zero-age main sequence (the red line) and are not yet hot enough to derive all of their energy from the fusion of hydrogen.

There are real star clusters that fit this description. The first to be studied (in about 1950) was NGC 2264, which is still associated with the region of gas and dust from which it was born ([link]).

Image of the Young Cluster N G C 2264. This youthful cluster derives its name from the shape outlined by its brightest stars. The “Christmas Tree” is upside down in this image. The brightest star at the top of the frame is the base of the tree. The top of the tree is the star above the dark v-shaped lane in the nebula just left of the center at the bottom of the image. — **Figure 2.** Located about 2600 light-years from us, this region of newly formed stars, known as the Christmas Tree Cluster, is a complex mixture of hydrogen gas (which is ionized by hot embedded stars and shown in red), dark obscuring dust lanes, and brilliant young stars. The image shows a scene about 30 light-years across. (credit: ESO)

The NGC 2264 cluster’s H–R diagram is shown in [link]. The cluster in the middle of the Orion Nebula (shown in [link] and [link]) is in a similar stage of evolution.

In this plot the vertical axis is labeled “Luminosity (LSun)” and goes from 0.1 at the bottom to 100,000 at the top. The horizontal axis is labeled “Surface Temperature (K)” and goes from 40,000 on the left to 3,000 on the right. The zero-age main sequence is drawn as a red diagonal line starting just above 100,000 LSun at the top of the graph down to about 4000 K at the bottom. Over plotted are the observed values of stars in N G C 2264, shown as black dots. Stars lie on the line until about 10000 K and 10 LSun, below which the stars reside above the main sequence.

As clusters get older, their H–R diagrams begin to change. After a short time (less than a million years after they reach the main sequence), the most massive stars use up the hydrogen in their cores and evolve off the main sequence to become red giants and supergiants. As more time passes, stars of lower mass begin to leave the main sequence and make their way to the upper right of the H–R diagram.

To see the evolution of a star cluster in a dwarf galaxy, you can watch this brief animation of how its H–R diagram changes.

[link] is a photograph of NGC 3293, a cluster that is about 10 million years old. The dense clouds of gas and dust are gone. One massive star has evolved to become a red giant and stands out as an especially bright orange member of the cluster.

Image of N G C 3293. This compact cluster of bright, blue stars is located near the center of this image surrounded by the red wisps of ionized hydrogen left over after the cluster’s formation. — **Figure 4.** All the stars in an open star cluster like NGC 3293 form at about the same time. The most massive stars, however, exhaust their nuclear fuel more rapidly and hence evolve more quickly than stars of low mass. As stars evolve, they become redder. The bright orange star in NGC 3293 is the member of the cluster that has evolved most rapidly. (credit: ESO/G. Beccari)

[link] shows the H–R diagram of the open cluster M41, which is roughly 100 million years old; by this time, a significant number of stars have moved off to the right and become red giants. Note the gap that appears in this H–R diagram between the stars near the main sequence and the red giants. A gap does not necessarily imply that stars avoid a region of certain temperatures and luminosities. In this case, it simply represents a domain of temperature and luminosity through which stars evolve very quickly. We see a gap for M41 because at this particular moment, we have not caught a star in the process of scurrying across this part of the diagram.

In panel (a), on the left, the vertical axis is labeled “Luminosity (LSun)” and goes from 0.1 at the bottom to 100,000 at the top. The horizontal axis is labeled “Surface Temperature (K)” and goes from 40,000 on the left to 3000 on the right. The zero-age main sequence is drawn as a red diagonal line starting just above 100,000 LSun at the top of the graph down to about 4000 K at the bottom. Over plotted are the observed values of the stars in M 41. Approximately half of the stars lie above the main sequence until around 9000 K and 50 LSun, below which the stars all lie on the main sequence. On the right side of the diagram, a small grouping of giant stars are centered around 4000 K and 50 LSun. Panel (b), on the right, shows a photograph of the open cluster M 41.

H–R Diagrams of Older Clusters

After 4 billion years have passed, many more stars, including stars that are only a few times more massive than the Sun, have left the main sequence ([link]). This means that no stars are left near the top of the main sequence; only the low-mass stars near the bottom remain. The older the cluster, the lower the point on the main sequence (and the lower the mass of the stars) where stars begin to move toward the red giant region. The location in the H–R diagram where the stars have begun to leave the main sequence is called the main-sequence turnoff.

Hypothetical H-R Diagram of an Older Cluster. In this plot titled “M 2001 Age: 4240 million years,” the vertical axis is labeled “Luminosity (LSun)” and goes from 0.1 at the bottom to 100,000 at the top. The horizontal axis is labeled “Surface Temperature (K)” and goes from 40,000 on the left to 3000 on the right. The zero-age main sequence is drawn as a red diagonal line starting just above 100,000 LSun at the top of the graph down to about 4000 K at the bottom. Over-plotted on the graph are black dots representing the individual stars in the cluster. Several of the stars are plotted above and to the right of the main sequence and represent the stars that have begun to enter the giant phase of their evolution. Below about 6500 K and 5 LSun the remaining stars lie on the main sequence. — **Figure 6.** We see the H–R diagram for a hypothetical older cluster at an age of 4.24 billion years. Note that most of the stars on the upper part of the main sequence have turned off toward the red-giant region. And the most massive stars in the cluster have already died and are no longer on the diagram.

The oldest clusters of all are the globular clusters. [link] shows the H–R diagram of globular cluster 47 Tucanae. Notice that the luminosity and temperature scales are different from those of the other H–R diagrams in this chapter. In [link], for example, the luminosity scale on the left side of the diagram goes from 0.1 to 100,000 times the Sun’s luminosity. But in [link], the luminosity scale has been significantly reduced in extent. So many stars in this old cluster have had time to turn off the main sequence that only the very bottom of the main sequence remains.

H-R Diagram of 47 Tucanae. In this plot the vertical axis is labeled “Luminosity (LSun)” and goes from 0.01 near the bottom to 100 near the top. The horizontal axis is labeled “Surface Temperature (K)” and goes from 6000 on the left to 3000 on the right. Black dots represent observations of the stars in 47 Tuc. The giant and supergiant branches are seen above Luminosity =1, where the main sequence turn-off begins. The main sequence is well defined from L=1 down to L=0.01, below which there is scatter in the data points due to the faintness of these low-mass stars. — **Figure 7.** This H–R diagram is for the globular cluster 47. Note that the scale of luminosity differs from that of the other H–R diagrams in this chapter. We are only focusing on the lower portion of the main sequence, the only part where stars still remain in this old cluster.

Check out this brief NASA video with a 3-D visualization of how an H–R diagram is created for the globular cluster Omega Centauri.

Just how old are the different clusters we have been discussing? To get their actual ages (in years), we must compare the appearances of our calculated H–R diagrams of different ages to observed H–R diagrams of real clusters. In practice, astronomers use the position at the top of the main sequence (that is, the luminosity at which stars begin to move off the main sequence to become red giants) as a measure of the age of a cluster (the main-sequence turnoff we discussed previously). For example, we can compare the luminosities of the brightest stars that are still on the main sequence in [link] and [link].

Using this method, some associations and open clusters turn out to be as young as 1 million years old, while others are several hundred million years old. Once all of the interstellar matter surrounding a cluster has been used to form stars or has dispersed and moved away from the cluster, star formation ceases, and stars of progressively lower mass move off the main sequence, as shown in [link], [link], and [link].

To our surprise, even the youngest of the globular clusters in our Galaxy are found to be older than the oldest open cluster. All of the globular clusters have main sequences that turn off at a luminosity less than that of the Sun. Star formation in these crowded systems ceased billions of years ago, and no new stars are coming on to the main sequence to replace the ones that have turned off (see [link]).

Simplified H-R Diagrams for Clusters of Different Ages. Each of the three diagrams in this figure have the vertical axis labeled “Luminosity” in arbitrary units and the horizontal axis labeled “Temperature” in arbitrary units. Each also has the “Zero-age Main Sequence” drawn as a red line running from the top left of the diagram to the bottom right. The stars in each diagram are represented as a solid black line. In the left-most diagram, labeled “New-born,” all the cluster stars lie on the Z A M S. The diagram at center is labeled “100 million years,” with the giant branch turning away from the Z A M S in the upper left portion of the diagram. Finally, in the right hand diagram, labeled “10 billion years,” the giant branch turns off the Z A M S in the lower right portion of the diagram. — **Figure 8.** This sketch shows how the turn-off point from the main sequence gets lower as we make H–R diagrams for clusters that are older and older.

Indeed, the globular clusters are the oldest structures in our Galaxy (and in other galaxies as well). The youngest have ages of about 11 billion years and some appear to be even older. Since these are the oldest objects we know of, this estimate is one of the best limits we have on the age of the universe itself—it must be at least 11 billion years old. We will return to the fascinating question of determining the age of the entire universe in the chapter on The Big Bang.

Key Concepts and Summary

The H–R diagram of stars in a cluster changes systematically as the cluster grows older. The most massive stars evolve most rapidly. In the youngest clusters and associations, highly luminous blue stars are on the main sequence; the stars with the lowest masses lie to the right of the main sequence and are still contracting toward it. With passing time, stars of progressively lower masses evolve away from (or turn off) the main sequence. In globular clusters, which are all at least 11 billion years old, there are no luminous blue stars at all. Astronomers can use the turnoff point from the main sequence to determine the age of a cluster.

Glossary

main-sequence turnoff: location in the H–R diagram where stars begin to leave the main sequence

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