Unit 3 WebQuest - Internet Project

Out of this World

Introduction | Task | Process | Guidance | Conclusion | Questions

Introduction
You can probably name the planets in the solar system, but can you name planets outside of our system? In recent years, planets in other systems have been discovered. In August, 2004, a team of astronomers discovered a small planet orbiting a star known as 55 Cancri. Star 55 Cancri has three other planets, making it the first known four-planet system outside our system.

Some Observatories in California

Name

Location

Lick Observatory

Santa Cruz

Table Mountain Facility

Wrightwood

Mount Wilson Observatory

Pasadena

Owens Valley Radio Observatory

Bishop

Reuben H. Fleet Science Center Planetarium

San Diego

In this project, you will examine how scientific notation, factors, and graphs are useful in presenting information about planets.

The Task
Since 1997, NASA has sponsored an annual Space Day in which schools everywhere can participate. Your school will be joining in the celebration this coming year by investigating space and technology for the entire day. Your class has been assigned to design a display about the planets in our solar system. Each student in your class needs to contribute some type of planetary information that can be described using mathematics. For this project you need to present your information in a brochure, on a poster, or on a Web page. Be sure you include the following information:

The Process
To successfully complete this project, you will need to complete the following items.

Guidance
Here are some additional questions and ideas you may want to consider for your project.
  1. What missions to investigate the planets of our solar system have been completed or are in progress? What were the results of these missions?
  2. How many moons do the various planets have? Have there been any space missions to these moons?
  3. Have other solar systems been located? If so, how far are they located from Earth?
  4. How do telescopes work? What is the history of telescopes? What are the various types of telescopes?
  5. How do the missions and research conducted by NASA benefit people on Earth?
  6. Have any companies begun to develop plans for space travel for civilians? What are the advantages and disadvantages of such programs?
  7. Investigate Kepler's Laws. Verify the third law for each of the nine planets.
  8. What is a light-year?
  9. What discoveries have been made by the Hubble Space Telescope?
  10. What is the eccentricity of an orbit? How is it calculated? Find the eccentricity of the orbit of each planet.

Conclusion
Here are some ideas for concluding your project.

Questions

Lesson 7–1
For her project, Priscilla finds these data about the planets on a Web site. The table shows the perihelion (closest point to the Sun), the aphelion (furthest point from the Sun), and the average surface temperature for each planet. Notice that all distances are given as 106 miles.

Planet

Perihelion
(106 miles)

Aphelion
(106 miles)

Average
Temperature (°F)

Mercury

28.6

43.4

333

Venus

66.8

67.7

867

Earth

91.4

94.5

59

Mars

128.4

154.9

–85

Jupiter

507.4

4331

–166

Saturn

941.1

10,747

–220

Uranus

1866.4

30,589

–320

Neptune

2824.5

59,800

–330

Pluto

4538.7

90,588

–375

Source: www.nasa.gov
  1. Copy the table and rewrite all the distances in scientific notation.
  2. For which planet is the difference between the aphelion and perihelion the greatest?
  3. Draw a scatter plot for the perihelion distance and the average temperature. Let distance be on the horizontal axis and temperature on the vertical axis.
  4. Describe the scatter plot.

Lesson 8–1
For his project, Tyler makes a table that would help students and teachers make a scale model of the solar system. To start, he decides to average the perihelion and aphelion distances for the model. The table shows the distances.

Planet

Perihelion
(106miles)

Aphelion
(106miles)

Average Distance
(106miles)

Mercury

28.6

43.4

 

Venus

66.8

67.7

 

Earth

91.4

94.5

 

Mars

128.4

154.9

 

Jupiter

507.4

4331

 

Saturn

941.1

10,747

 

Uranus

1866.4

30,589

 

Neptune

2824.5

59,800

 

Pluto

4538.7

90,588

 

Source: www.nasa.gov
  1. Fill in the average distance column. Write your answers as values in 106 miles.
  2. What is a common factor of all the distances in column four?
  3. Suppose you round each value in column 4 to the nearest 10. What is the greatest common factor of each distance then?
  4. How can factoring the values for the distances help Tyler to make a scale model of the solar system?

Lesson 9–2
For her project, Ingrid decides to find the surface area of each planet. She makes this table that shows the diameter of each planet.

Planet

Diameter
(miles)

Radius

Surface Area
(square miles)

Mercury

3032

 

 

Venus

7521

 

 

Earth

7926

 

 

Mars

4222

 

 

Jupiter

88,846

 

 

Saturn

74,897

 

 

Uranus

31,763

 

 

Neptune

30,775

 

 

Pluto

1485

 

 

Source: www.nasa.gov
  1. In a reference book, Ingrid finds that the surface area of a sphere is found by multiplying 4 times p times the radius squared. The formula is written SA = 4 x p x r2. Fill in column three by finding the radius of each planet. Then fill in column four by finding the surface area of each planet. Use 3.14 for p and round each answer to the nearest whole number.
  2. Next, Ingrid decides to make a scatter plot of the data. She writes the ordered pairs (radius, surface area) and plots the points. Draw this scatter plot. Describe the scatter plot.
  3. Ingrid uses graphing software to find an equation for the scatter plot. The equation is y = 12.56x2. Explain why this equation fits the data.
  4. The graph of y = 12.56x2 lies in Quadrants I and II. In which quadrant does the graph have no meaning for the surface area of the planets? Explain.

TEACHER NOTES

In this project, students will research statistics about the planets of the solar system and present these statistics in some manner. They can use any type of graphs, tables, or calculations to present the statistics. Students should examine the ideas in the Exercises presented in Lessons 7-1, 8-1, and 9-2 for ideas. Encourage students to brainstorm with others to find a suitable project. If students are having trouble deciding upon a topic, just have them make graphs of various statistics about the planets, such as distance from the Sun, and/or make scatter plots of various statistics to look for relationships. Another option for this project is to have all students make a table to show the distances that could be used to make a model of the solar system (See Lesson 8-1.). Students would probably all choose different scales to use. Spreadsheet software would be helpful for students making scale models and for students who want to compare various statistics about the planets with scatter plots as was done in Exercise 3 in Lesson 7-1.

The Guidance section of the Cross Curricular Project contains questions that would be good for a whole-class discussion and for providing interdisciplinary connections. You may want to collaborate with a science teacher at your school for this project. If you prefer, have each student research one of the questions in the Guidance section and add the information they find to the final presentation of their Cross Curricular Project.

Several Web sites are included in the project to help students in completing this Cross Curricular Project. Encourage students to find additional sites and to share those sites with other students.

Students will work on this project in Unit 3.
Lesson

7–1

8–1

9–2
Page

362

421

484

ANSWERS
Lesson 7–1


  1. Planet

    Perihelion
    (106miles)

    Aphelion
    (106miles)

    Difference in
    Distances

    Mercury

    2.86 x 107

    4.34 x 107

    1.48 x 107

    Venus

    6.68 x 107

    6.77 x 107

    0.09 x 107

    Earth

    9.14 x 107

    9.45 x 107

    0.31 x 107

    Mars

    1.284 x 108

    1.549 x 108

    0.265 x 108

    Jupiter

    5.074 x 108

    4.331 x 109

    3.8236 x 109

    Saturn

    9.411 x 108

    1.0747 x 1010

    9.8059 x 109

    Uranus

    1.8664 x 109

    3.0589 x 1010

    2.87226 x 1010

    Neptune

    2.8245 x 109

    5.98 x 1010

    5.69755 x 1010

    Pluto

    4.5387 x 109

    9.0588 x 1010

    8.60493 x 1010

  2. Pluto

  4. If the points were connected, the graph would be a curve. As distance increases, temperature decreases.

Lesson 8–1

  1. Planet

    Average Distance (106miles)

    Mercury

    36

    Venus

    67.25

    Earth

    92.95

    Mars

    141.65

    Jupiter

    2419.2

    Saturn

    5844.05

    Uranus

    16,227.7

    Neptune

    31,312.25

    Pluto

    47,563.35

  2. 106

  3. Planet

    Average Distance (106 miles)

    Mercury

    40

    Venus

    70

    Earth

    90

    Mars

    140

    Jupiter

    2420

    Saturn

    5840

    Uranus

    16,230

    Neptune

    31,310

    Pluto

    47,560

    107
  4. Sample answer: Tyler could factor 107 out of each distance and let 1 cm be equal to 107 miles. For example, the distance from the Sun to Mercury would then be 4 cm and the distance from Earth to the Sum would be 9 cm.

Lesson 9–2

  1. Planet

    Radius
    (miles)

    Surface Area
    (square miles)

    Mercury

    1516

    28,866,095

    Venus

    3760.5

    177,615,485

    Earth

    3963

    197,259,435

    Mars

    2111

    55,971,392

    Jupiter

    44,423

    24,785,940,790

    Saturn

    37,448.5

    17,614,020,310

    Uranus

    15,881.5

    3,167,908,851

    Neptune

    15,387.5

    2,973,895,963

    Pluto

    742.5

    6,924,407



  2. If the points were connected, the graph would be a curve. It looks like part of the graph of a parabola.
  3. If y is the surface area of a sphere and x is the radius, then an equation relating the two variables is y = 4 • 3.14 • x2. If you multiply the two constants, you get y = 12.56x2
  4. The graph has no meaning for this situation in Quadrant II. The values of x are negative in Quadrant II. The radius is represented by x and you cannot have negative values for the radius.