2 - the scale solar system - university of delawareowocki/phys133/2-scalesolarsystem.pdf · as you...
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UDel Physics 1 of 7 Fall 2017
PHYS133–Lab2ScaleModeloftheSolarSystemGoals: • To get an idea of the scale of the solar system with the sizes of the planets. • To be able to correctly change from “real” distances to scale distances. What You Turn In: • The tables, answers to questions and completed maps found in the lab (or larger maps provided by your
instructor).
BackgroundReading:Background reading for this lab can be found in your text book (specifically, Chapters 1 – 3 and section 6.1) and the notes for the course.
Equipmentprovidedbythelab:Computer with Internet Connection
• Rulers • Protractor • Compass • Ledger size maps of UD’s Newark Campus
Equipmentprovidedbythestudent:
• Pen • Calculator
Background:The scale model of the solar system was installed on the University of Delaware’s main campus through a grant from the Annie Jump Cannon fund and the National Science Foundation. Although the years have weathered the markers, the name of each planet is easy to read on each marker. The eight planet markers (and on dwarf planet marker) are placed at an appropriate distance from the Sun marker. The Sun marker is located near the base of the front steps to the Old Main building. Each marker states where the next marker in the scale system is located. This may be difficult to read, so the table and image on the next page provides approximate locations. The linear sizes are to scale. The large round part of the maker represents the size of the sun. In reality, the sun is 1,390,000 km in diameter. This is about 109 times the diameter of the Earth. As you travel the scale solar system, look to see if you can see any of the other markers. You should note the size of each planet and how “visible” it would be to you noting its diameter. You will need to accurately locate the sun and the planets known to the ancients on your maps prior to attending lab.
PHYS133 Lab 2 Scale Model of the Solar System
UDel Physics 2 of 7 Fall 2017
WheretheMarkersAre:The Sun – the steps of Old College. Mercury – front side of Recitation Hall. Venus – back side of Recitation Hall. Earth – east of Willard Hall on the walk on the South side of McDowell. Mars – South side of Main Street near Brown Hall. Jupiter – front of Sharp Lab. Saturn – Mall side of the Morris Library on near the steps. Uranus – North side of Courtney Street between Manuel and Haines Streets (near a telephone). Neptune – in the Botanical Garden near Worrilow Hall. Pluto – the prototypical Ice Dwarf Planet, is in front of the Rust Ice Arena.
Note we are going to take our view as looking down from above the North Pole of the sun. All the planets travel counter-clockwise in their orbits.
PHYS133 Lab 2 Scale Model of the Solar System
UDel Physics 3 of 7 Fall 2017
Before you begin, make sure you read the entire lab including the description of what will be due after the lab is completed!
ExperimentalProcedure:1. On Map 1, plot the Sun marker and markers for Mecury, Venus, Earth and Mars.
2. On Map 2, plot the Sun marker and markers for Mars, Jupiter and Saturn.
3. Using a compass draw a circular orbit for each planet, centered on the Sun.
4. Now, using the information given in Table 1, if the Sun and Earth markers denote where they would be today, plot the
positions of each of the other planets for today as given. a. Draw a light reference line from the Earth to the Sun. b. Centered on the Earth, measure the appropriate angle to the planet (East is counter-clockwise). c. The planet is where the line intersects the appropriate orbit. Mark it!
If it intersects twice (as it may for the inferior planets) use the clue of increasing or decreasing angle size to determine which point the planet is located.
USE DIFFERENT symbols for the marker, today and one year from today. Denote which orbit belongs to each plaent.
Remember, when looking up at the sky, if you lie on on your back with North being above your head, East is to the left. So we measure East direction as being counter clockwise from the sun with West being clockwise from the sun.
5. Now, knowing how long it takes each planet to go around the sun, plot the position of each planet one year from now.
a. Look up online or in your text book the orbital (or revolution) period of each planet. b. Determine how many degrees the planet travels around its orbit in 365 Earth days. This is the Posistion Change
in one year. The inferior planets should travel around more than one orbit, the superior planets should travel around less than one orbit. Where is the Earth in One Earth Year?
c. Centered on the Sun, measure the appropriate angle the planet has moved. Again, remember the planets orbit in an East (i.e., counter-clockwise) direction.
d. Where the line intersects the appropriate orbit is the location of the planet. Mark it!
6. On a line that connects the Earth to the planet’s new location (one year from now), find its angle relative to the sun
and write it down in Table 1.
7. Fill in the missing data in Table 2 below, by finding the scale. I.e., 1m on campus = how many kilometers in the real solar system?
8. In the lab there are various balls. Determine which is the most accurate for the Earth, Sun and other objects your TA suggests. Write these down at the end.
PHYS133 Lab 2 Scale Model of the Solar System
UDel Physics 4 of 7 Fall 2017
Table 1 – Planet Locations
Planet
Length of Year
(in earth years)
Elongation (Position as seen from
Earth relative to Sun) on September 11, 2017
Position change from September 11, 2017 to
September 11, 2018 Position Relative to the
Sun on September 11, 2018 Mercury
0.24 18º W increasing
Venus
0.61 30º W decreasing
Mars
1.88 15º W
Jupiter
11.83 36º E
Saturn
29.41 93º E
Table 2 – Scale Data for Planet Sizes and Orbits
Object Diameter (km) Diameter Distance (km) Distance Scale
(cm) from the Sun Scale (m)
Sun 1,390,000 58.33 0
Mercury 4,900
58,000,000
Venus 12,200
108,000,000
Earth 12,756
150,000,000
Mars 6,794
227,940,000
Jupiter 142,984
778,330,000
Saturn 120,536
1,429,400,000
Rings 250,000
Uranus 51,118 2.15 2,870,990,000 1,205
Neptune 49,532 2.08 4,504,000,000 1,890
Pluto 2,274 0.10 5,913,000,000 2,481
PHYS133 Lab 2 Scale Model of the Solar System
UDel Physics 5 of 7 Fall 2017
Table 3 – Scale Data for Major Moons
Object Diameter (km) Diameter Distance (km) Distance Scale
(cm) from planet Scale
(cm)
Moon (Earth)
3,476.00 384,400
Phobos (Mars)
22.20 9,378
Deimos (Mars)
12.60 23,459
Io (Jupiter)
3,630.00 422,000
Europa (Jupiter)
3,138.00 670,900
Ganymede (Jupiter)
5,262.00 1,070,000
Callisto (Jupiter)
4,800.00 1,883,000
Titan (Saturn)
5,150.00 1,221,830
What is the speed of light on this scale? On your maps, are there any planets that have a maximum elongation (i.e., largest angle they can appear) from the sun? For these planets what are the maximum elongations?
What do you notice about the distances between the inner planets to their nearest neighbors vs. outer planets?
What is in the space between the planets?
PHYS133 Lab 2 Scale Model of the Solar System
UDel Physics 6 of 7 Fall 2017
Map1
PHYS133 Lab 2 Scale Model of the Solar System
UDel Physics 7 of 7 Fall 2017
Map2
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