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NOVA scienceNOW: 10th Planet
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Viewing Ideas
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Before Watching
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Discuss the following questions as a class:
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Why is it important to have a clear definition of a planet?
A clear definition would help astronomers know how to
classify new objects they discover. For example, if size
were the only criteria, some asteroids could be considered
to be planets.
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Why is it important, in science, to classify objects and use
precise vocabulary?
Grouping and classifying objects helps us compare,
contrast, and draw connections. Precise vocabulary aids
our ability to accurately describe objects and understand
the way they relate to one another.
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How do advancing technologies make it increasingly necessary
to have a clear definition?
New technologies, such as telescopes, computers, and
spacecraft, have aided scientists in discovering new
bodies that orbit our sun as well as those that orbit
distant stars. These bodies need names, categories, and
definitions so people can discuss them unambiguously.
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Some scientists do not believe Pluto is a planet. They say it is
smaller than Earth's moon, its mass is far less than that of the
other planets, and its orbit is unlike any other (Its orbit is tipped 17 degrees compared to Earth's. This
orbital tilt is considerably different from the other eight
planets.) On the board, write the mass and diameter of the nine planets
and have students calculate how Pluto compares. Ask them if the
data suggest that size should be an important part of the
definition of a planet.
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Mercury
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Venus
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Earth
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Mars
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Jupiter
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Saturn
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Uranus
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Neptune
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Pluto
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Mass (x1024 kg)
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0.330 |
4.87 |
5.97 |
0.642 |
1899 |
568 |
86.8 |
102 |
0.0125 |
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Diameter (km)
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4879 |
12,104 |
12,756 |
3475 |
142,984 |
120,536 |
51,118 |
49,528 |
2390 |
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Have student pairs match astronomy words to their definitions.
You can read out a definition and see if students can name the
term. Alternatively, say the term and ask for a definition.
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Astronomy Term
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Definition
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Universe
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The space that contains all existing matter and energy
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Solar System
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A sun and the celestial objects bound to it by gravity
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Inner Planets
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Planets and their moons that formed closest to a sun.
(For example: Mercury, Venus, Earth, and Mars)
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Terrestrial Planets
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Another name for the four inner planets, because they
are dense and rocky
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Outer Planets
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Planets beyond Mars, sometimes called the Jovian
planets or gas giants due to their composition and size.
These include Jupiter, Saturn, Uranus, and Neptune.
Pluto is sometimes included with the outer planets, but
it is small, solid, and its composition is more like an
asteroid than a gas giant.
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Satellite
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An object that orbits another object
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Asteroids
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Small (i.e. boulder size to a few kilometers in length)
solid objects that orbit the sun, mostly in a belt
between Mars and Jupiter
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Comets
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Frozen gas-and-ice bodies orbiting the sun in large,
elliptical orbits that extend beyond Pluto
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Kuiper Belt
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Disc-shaped region of icy debris orbiting the sun at a
distance of 12-15 billion kilometers from the sun
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After Watching
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Ask students what technologies astronomers use to observe the
heavens. (Telescopes, satellites, charge-coupled device (CCD) cameras,
computers, and conventional cameras) Ask them to speculate about how advancing technology has
affected our understanding of the solar system and universe.
Before 1600, people observed the sky with the naked eye. They
thought the universe had eight bodies: the sun, Earth, Earth's
moon, Mercury, Venus, Mars, Jupiter, and Saturn. They
considered Earth to be the center, with the other bodies
revolving around it. After the advent of the telescope in the
17th century, people realized that the sun occupied
the center of the solar system, with the planets in elliptical
orbits around it. Today, astronomers use spacecraft,
ground-based telescopes, computers, and CCD and conventional
cameras to study space. Many thousands of objects have been
discovered, and our conception of the universe continues to
evolve.
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Tell students that the speed of light is about 300,000 km per
second. Using the distances in the table below, have pairs of
students use calculators to find how long it takes light to
travel from the sun to each planet. Discuss that sunlight
reflects off planets, and that, when we see starlight, we are
actually looking back in time to when the light left the star
long ago.
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Mercury
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Venus
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Earth
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Mars
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Jupiter
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Saturn
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Uranus
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Neptune
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Pluto
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Distance from sun
(x106 km)
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57.9 |
108.2 |
149.6 |
227.9 |
778.6 |
1433.5 |
2872.5 |
4495.1 |
5870.0 |
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Time (minutes)
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3.2 |
6.0 |
8.3 |
12.7 |
43.3 |
79.6 |
159.6 |
249.7 |
326.1 |
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Extension: Have students calculate how long it would take to fly
from the sun to each planet if they were in a plane averaging
900 km per hour.
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Scientist Neil deGrasse Tyson discusses how students' knowledge
of planets is often limited to naming and ordering them based on
their approximate distance from the sun. To help students learn
more about the formation and composition of the terrestrial
planets and Earth's moon, make 10 groups of students. Assign
each one a planet or the moon. Have them research their
celestial object and make a poster that includes: its size,
distance from the sun, composition, surface temperature
(average, high, low), and any other interesting facts they find.
Have students determine what a "typical day" is on their planet.
Does it have seasons or precipitation? What might astronauts
need to survive this object? Ask groups to choose a term to
describe their object's "personality," such as a flighty comet,
a sleepy moon, or an angry or mysterious planet. Have them share
their posters and hang their work on a wall at relative
distances from the sun (see scale in After Viewing question 2).
As an assessment, ask students to name some characteristics of
the inner planets and of the outer gas giants.
Web Sites
Hands-on Universe
www.handsonuniverse.org/
Allow students to examine the planets and objects in the universe.
Welcome to the Planets
pds.jpl.nasa.gov/planets/welcome.htm
Includes planet profiles, photographs, and information about the
space-exploration missions.
Windows to the Universe
www.windows.ucar.edu/
Consists of leveled sections for students, teacher resources, and
information about space missions, our solar system, and other bodies
in the universe.
Books
DK Guide to Space by Peter Bond. Dorling Kindersley, 1999.
Includes many NASA photographs and explores the solar system and
beyond.
Skywatching by David H. Levy and John O'Byrne (editor).
Time-Life Books, 2000.
Describes the planets, the sun, comets, and eclipses, and includes
photographs and sky-viewing charts.
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