Introduction

Chapter 2. Motions of Stars

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Author: Scott Miller, Pennsylvania State University

Editor: Grace L. Deming, University Of Maryland

Star Figure

The goals of this module: At the end, you should be able to:

  1. Explain why stars appear to rise and set.
  2. Determine the path of a star depending on where it rises.
  3. Determine the path of a star depending on where you are located on Earth.

In this module you will explore:

  1. The rise and set positions of stars as observed from mid-northern latitudes
  2. The path a star will follow as it rises in the east and sets in the west
  3. How the path of a star changes with the latitude of the observer

Why you are doing it: Since ancient times, people have noticed that the positions of stars move across the sky. By completing this activity, you will not only understand why the stars appear to move over time, but in what manner they appear to move, and how that motion varies for observers at different latitudes.

Celestial Earth Figure

While today we know that stars lie at various distances from Earth, this was not always common knowledge. Ancient astronomers believed that all stars were fixed on a sphere surrounding Earth, called the celestial sphere. While this is not true, astronomers find this model of a celestial sphere helpful in visualizing the positions and motions of celestial objects.

For a person standing on Earth, he can view the half of the celestial sphere above his horizon. The horizon is defined as the boundary where the ground meets the sky. An observer can see everything above his horizon, but the ground blocks his view of everything below it.

Look at the figure to the right. In it you can see a person standing on Earth at a latitude of 35°N. His horizon is indicated as a plane, which bisects the celestial sphere. The person can see everything on the top half of the celestial sphere, but nothing on the bottom half. To indicate directions on Earth, we have created a system of coordinates based on a person's position on Earth. When facing the North Pole, a person is facing north, while south is in the opposite direction. In this orientation, east is to the right, while west is to the left. Keep in mind that these labels pertain to directions on Earth only! They do not pertain to directions in space.

As you watch the animation below, you will notice that the observer's view of the sky changes; what he can see at one point in time changes as the celestial sphere rotates. Remember, it is really the rotating Earth that produces this motion. You can try deselecting "fix earth" to see earth rotating.

Earth and the Stars Animation

Question 1.

In which direction would you look to see the stars rising above the horizon?

A.
B.
C.
D.

3
Try again. Watch the animation in “Earth View” mode. Over which horizon do the stars appear to be rising?
Correct. Holding Earth still, you see the stars on the celestial sphere rise over the eastern horizon as time goes on.
Incorrect. Holding Earth still, you see the stars on the celestial sphere rise over the eastern horizon as time goes on.

Let's change our point of view from space to the observer on Earth. In the animation set the direction to 180° - pointing east. Then select "view from earth". Directly in front of us represents the direction we are facing (in this case, east). The left corner represents the horizon on our left (in this case north). The right corner represents the horizon on our right (in this case south). Here we see what the observer will see as he watches the stars rise above the horizon. You can also change the "look up" angle to 90° to view the zenith (the point directly overhead).

Earth and Stars Animation

Question Sequence

Question 2.

Do all stars rise exactly due east?

A.
B.

Correct. While stars in general rise from the eastern horizon, they do not all rise from exactly due east. Some rise north of east, while others rise south of east (and some do rise exactly due east), but you will never see stars rise over the western horizon.
Incorrect. While stars in general rise from the eastern horizon, they do not all rise from exactly due east. Some rise north of east, while others rise south of east (and some do rise exactly due east), but you will never see stars rise over the western horizon.

Due to the rotation of Earth and the observer's latitude, all stars will trace out paths parallel to each other. In the animation below check "Leave trails" to see the trails of 3 stars.

Earth and Stars Animation

Question Sequence

Question 4.

For an observer positioned at latitude 35°N where would a star which does pass overhead rise?

A.
B.
C.

3
Try again. Look at the three star paths. Which one passes directly overhead (remember, the zenith point is at the top of the semi-circle)?
Correct. Because the star paths are slanted relative to the horizon for an observer at mid-northern latitudes, the star which passes overhead must have risen north of East.
Incorrect. Because the star paths are slanted relative to the horizon for an observer at mid-northern latitudes, the star which passes overhead must have risen north of East.

Summary

How would you describe the path of a star which rises due east and sets due west for a person living in the northern hemisphere?

In which direction would it move as it rises above the horizon and in which direction you would have to face when viewing it highest in the sky?

Based on what we've discovered above, stars which rise due east will move southward as they get higher in the sky, such that when they reach their highest point you would need to face due south to see them. They would then move back northward as they appear to descend, until they set due west.

Everything we've done so far has been for a person who lives at mid-northern latitudes (specifically, around 35° N latitude.) Let's see how stars appear to move across the sky at other latitudes.

Click on the up and down latitude arrows to change the latitude and you will see how the celestial sphere is oriented and how the stars appear.

Make sure you check out these specific locations:

90° N latitude (the North Pole)
35° N latitude
0° Latitude (the Equator)
35° S latitude
90° S latitude (the South Pole)

Earth and Stars Animation

Question 6.

Is there any location on Earth where a star which rises exactly due east does pass directly overhead?

A.
B.
C.
D.

3
Try again. Explore a little more, watching the stars move at different latitudes. Do you notice any relationship between the observer's latitude and the angle the star paths make with the horizon?
Correct. If you watched closely, you may have noticed that the paths of the stars are more slanted relative to the horizon the closer you are to the equator. At the equator, all of the stars will appear to rise straight up, such that stars which rise due east will pass directly overhead before setting due west.
Incorrect.If you watched closely, you may have noticed that the paths of the stars are more slanted relative to the horizon the closer you are to the equator. At the equator, all of the stars will appear to rise straight up, such that stars which rise due east will pass directly overhead before setting due west.

Summary

If an observer on the equator observes stars rising straight up over the eastern horizon and setting straight down towards the western horizon, what would an observer at the North Pole see?

She would see the stars moving in horizontal circles parallel to the horizon; never rising nor setting.

What about observers in the southern hemisphere?

They would see exactly the same thing, but reversed. At mid-southern latitudes, stars which rise due east would move high through the northern sky before setting due west, and a star which passes directly overhead would have risen south of east before passing overhead and setting south of west.

Indepth Activity: Motions of Stars

Answer the following questions. You may use the animation as a reference.

Earth and Stars Animation

Question 7.

No matter where you are located, a star that rises:

A.
B.
C.
D.
E.

Correct.
Incorrect.

Question 8.

Stars at the north pole will appear to revolve ____________ around the sky while stars at the South Pole will appear to revolve ____________ around the sky.

A.
B.
C.
D.

Correct.
Incorrect.

Question 9.

Why do stars appear to rise and set?

A.
B.
C.
D.
E.

Correct.
Incorrect.

Question 10.

How does the rising and setting of stars change as you move up the globe from the equator to the pole?

A.
B.
C.
D.
E.

Correct.
Incorrect.

Question 11.

On the celestial sphere, what is the point directly overhead called?

A.
B.
C.
D.
E.

Correct.
Incorrect.

Question 12.

If one of NASA’s missions put a rover on another planet and stars were observed to rise in the west and set in the east, what could we conclude?

A.
B.
C.
D.
E.

Correct.
Incorrect.

Question 13.

At any one moment when you are out observing the night sky, you can see:

A.
B.
C.
D.
E.

Correct.
Incorrect.

Question 14.

For an observer at a mid-northern latitude, a star rises north of due east and passes directly overhead. Where will it set?

A.
B.
C.
D.

Correct. The lower the latitude, the more the star trails are slanted relative to the horizon.
Incorrect. The lower the latitude, the more the star trails are slanted relative to the horizon.

Question 15.

In the northern hemisphere, for a star which rises due east, who will observe it higher in the sky when it reaches its highest point?

A.
B.
C.
D.

Correct. The lower the latitude, the more the star trails are slanted relative to the horizon.
Incorrect. The lower the latitude, the more the star trails are slanted relative to the horizon.

Question 16.

An observer at 35° N latitude observes a star rise due east, while an observer at 35° S latitude also observes a star rise due east at the same time. Which of the following is false?

A.
B.
C.
D.

Correct. The maximum altitude a star which rises due east will reach depends only on the observers latitude. Since both observers are at the same latitude (albeit on opposite hemispheres), they will both see the star reach the same maximum altitude.
Incorrect. The maximum altitude a star which rises due east will reach depends only on the observers latitude. Since both observers are at the same latitude (albeit on opposite hemispheres), they will both see the star reach the same maximum altitude.

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