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ESCI 110: Solar System Page 1-1 Exercise 1 Introduction to the Solar System Introduction One of the challenges you face as a student in an introductory earth science class is to keep a sense of perspective about the earth as a system. It’s very easy to get lost in the details of various topics we will address, and loose sight of why these details are important and how various earth systems are interrelated. In this exercise we will consider the earth as just one among a number of objects in our solar system. Objectives Upon completion of this exercise, you should be able to: Distinguish the categories of objects in the solar system, including a star, planets, moons, comets, asteroids and meteorites Name the planets in order of their distance from the sun Appreciate the size of the earth relative to the scale of the solar system and the sizes of the other planets Materials One balloon Play Dough or modeling clay Metric ruler Metric measuring tape Brain in operational mode (preferably your own!) Background Information All of the following objects are part of the solar system. Make sure you can distinguish them for exam purposes: Star: An object so massive that nuclear fusion is triggered in its interior, and thus it shines. Planet: Too small trigger nuclear fusion, these relatively large objects orbit a star. Moon: Solid objects that orbit planets. Asteroid: Small bodies of rock and/or metal that have their own orbit around the sun. Comets: Small bodies made predominantly of ice rather than rock and metal. Meteorites: Remnants of small bodies that fall to earth. ESCI 110: Solar System Page 1-2 Pre Lab Questions: To be answered before you come to class. Read pages 612-614. 1. What is the name of the star that’s closest to the earth? ____________________________ 2. Which planet is closest in size to the earth? _____________________________________ 3. Based on their size, the planets fall into two groups. Which planets are similar in size to the earth, and thus considered terrestrial planets (list all 4)? __________________________________________________________________________________ a. Which is the largest of the terrestrial planets, and what is its diameter? __________________________________________________________________________________ b. Which planets can be grouped with Jupiter into the Jovian planets? __________________________________________________________________________________ c. Which is the smallest of the jovian planets and what is its diameter? __________________________________________________________________________________ d. The smallest Jovian planet is how many times larger than the largest terrestrial planet? __________________________________________________________________________________ 4. The sun is _______ times larger than the Earth and ___________ times larger than Jupiter? 5. Which group of planets is closer to the sun, the terrestrial planets or the Jovian planets? _____________________________________________________________________________ 6. What feature of the solar system separates the terrestrial planets from the jovian planets? ______________________________________________________________________________ 7. Pluto was recently demoted from its standing as a planet and was reclassified as a ‘dwarf planet.” Your textbook has not even caught up with this renaming. However, Pluto’s standing as a planet was always debated. Based on the information in your textbook, why have astronomers never been completely satisfied with labeling Pluto a planet? ____________________________________________________________________________ ____________________________________________________________________________ ESCI 110: Solar System Page 1-3 In-Class Activity The table below includes the basic data you will need to complete this exercise: Table 1.1 Solar System Data Table Name The Sun Mercury Venus Earth Mars Jupiter Saturn Uranus Neptune Pluto The Moon* Diameter Distance from Sun (in km) (in millions of km) 1,400,000 0 4,878 58 12,104 108 12,756 150 6,794 228 143,884 778 120,536 1427 51,118 2870 50,530 4497 2,445 5900 3,475 150 Relative Mass (Earth = 1) .056 .82 1.00 .108 317.87 95.14 14.56 17.21 .0002 * The Moon is 0.348 million kilometers from the Earth Data from Tarbuck & Lutgens, 1996, Earth, 5th Edition *The asteroid belt is about 258 million miles from the sun. Directions: For this exercise we will construct a scale model of the solar system. In a scale model, the size is reduced while accurately maintaining the relative proportions of all of the features included in the model. For our solar system, we will use a scale of 10,000 kilometers (approximately 6,200 miles) = 1 mm. Roughly 25 mm = 1 inch, so this is quite a dramatic conversion in scale. Start with the sun, and determine its diameter in the scale model. Set up your scale conversion formula like this: Sun’s diameter = 1,400,000 km X 1 mm 10,000 km *Note: The zeroes cancel out so you can also set up the problem as: 140 km x 1mm = _____________________ 1km ESCI 110: Solar System Page 1-4 When you set the problem up this way, the kilometers cancel out, and the answer comes out in millimeters. Now blow up your balloon until the diameter matches that in the scale model, and tie it off. Now go through and calculate the diameters of the Moon and the planets as they will be in our scale model. Fill in the answers in the blanks below, and, as always, be sure to write down the units of measurement for each one. You should round off each diameter to the nearest tenth of a millimeter, because we can’t possibly make our models any more accurately than that. Scale Diameters Mercury ______________ Saturn ______________ Venus ______________ Uranus ______________ Earth ______________ Neptune ______________ Mars ______________ Pluto ______________ Jupiter ______________ The Moon ______________ When you have completed these calculations, use the Play Dough or modeling clay you will be making a model of 1 planet. Ask your instructor which planet you are to model. The next step is to convert the distance of each planet from the sun into a scale distance that we can use in our model. The best way to do this is by using scientific notation. Let’s use Mercury as an example: 6 Mercury’s distance from the sun = 58 x 10 km X 1 mm 104 km = _______________ *Another way to set up this problem: 58x102 x 1mm (because 106 ÷ 104 = 102) 1km Now fill in the blanks for the distances to the planets from the sun. Scale Distances from the Sun Mercury ______________ Saturn ______________ Venus ______________ Uranus ______________ Earth ______________ Neptune ______________ Mars ______________ Pluto ______________ Jupiter ______________ The Moon ______________ ESCI 110: Solar System Page 1-5 We will now use the tape measure to lay out our scale model of the solar system. Answer the questions below based on this model. Follow-up Questions 8. Are the planets evenly spaced as you proceed outward from the Sun? _____ What pattern do you see in the spacing of the planets? a. Terrestrial planets? _____________________________________________________ b. Jovian planets? _________________________________________________________ c. Write a brief statement summarizing the overall spacing of the planets. ____________ _______________________________________________________________________________ ______________________________________________________________________________ 9. “Mass is a measure of the quantity of matter an object contains. The masses of the planets are listed on the table in relation to the mass of the Earth” – Tarbuck, Lutgens, Pinzke, Applications in Earth Science. a. Which planet is the most massive in the Solar System? _______________________________ b. How many more times massive is it than Earth? ____________________________________ c. Which planet is the least massive (Excluding Pluto) _________________________________ 10. The gravitational attraction of a planet is directly related to its mass. Which planet exerts the greatest pull of gravity? Explain. ___________________________________________________________________________ 11. Your weight is a function of the gravitational attraction of an object on your mass. On which planet (excluding Pluto) would you weigh the least? Explain. ___________________________________________________________________________ ___________________________________________________________________________ 12. The Moon orbits the earth at an average distance of .348 million kilometers. What is the distance between the earth and the Moon for our scale model (use the scale that you used at the beginning of the lab)? (show work in space below) Distance from the Moon to the Sun x 1mm 104 km ESCI 110: Solar System Page 1-6 a. Scale distance between earth and Moon: ___________ b. Place the earth and the Moon at their correct distance for our model, and compare the distance between the earth and Moon to the distance between the earth and Mars. How many times farther away is Mars in comparison to the Moon? ____________ c. What can you conclude about the difficulty of landing astronauts on Mars compared to the Apollo mission when astronauts landed on the Moon? ______________________________________________________________________________ ______________________________________________________________________________