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... 1 Which planet has the greatest surface gravity? 2 Which planet has the greatest mass relative to Earth? 3 Do you agree with the statement 'Planets with the greatest mass have the greatest surface area'? Explain your answer. 4 Which planet has the lowest surface gravity? 5 Which planet has the small ...
... 1 Which planet has the greatest surface gravity? 2 Which planet has the greatest mass relative to Earth? 3 Do you agree with the statement 'Planets with the greatest mass have the greatest surface area'? Explain your answer. 4 Which planet has the lowest surface gravity? 5 Which planet has the small ...
Beyond Pluto: A new 9th planet? | Science News for Students
... tenth largest object orbiting the sun. solar system The eight major planets and their moons in orbit around the sun, together with smaller bodies in the form of dwarf planets, asteroids, meteoroids and comets ...
... tenth largest object orbiting the sun. solar system The eight major planets and their moons in orbit around the sun, together with smaller bodies in the form of dwarf planets, asteroids, meteoroids and comets ...
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... • Comets are composed of dust, ice and rock • Most comets originate in the Kuiper Belt and the Oort Cloud • Ever so often a comet gets close to Jupiter and Jupiter’s gravitations force will either capture the comet, or nudge the comet to change its orbit and enter the inner solar system ...
... • Comets are composed of dust, ice and rock • Most comets originate in the Kuiper Belt and the Oort Cloud • Ever so often a comet gets close to Jupiter and Jupiter’s gravitations force will either capture the comet, or nudge the comet to change its orbit and enter the inner solar system ...
Neptune discovery in physics class: activities and simulations
... • Period of revolution 84 years, average distance from the Sun is: 19 AU. • After 1800, discrepancies started to be apparent between the planet position as predicted by theory and as measured in the sky ...
... • Period of revolution 84 years, average distance from the Sun is: 19 AU. • After 1800, discrepancies started to be apparent between the planet position as predicted by theory and as measured in the sky ...
PHYS 185 Chapter 5 Highlights 1. Definition of a planet a. Who: The
... a. Discovered 1781 by Herschel – was charting faint stars and noticed this one moved against the background of stars b. Appears blue-green due to a methane atmosphere – methane absorbs long wavelength light (red), leaving short wavelengths (blue) to reflect c. Appears “tipped over” – axis of rotatio ...
... a. Discovered 1781 by Herschel – was charting faint stars and noticed this one moved against the background of stars b. Appears blue-green due to a methane atmosphere – methane absorbs long wavelength light (red), leaving short wavelengths (blue) to reflect c. Appears “tipped over” – axis of rotatio ...
Astronomers - duerkopscience
... revolve around the sun once • Size of a planets orbit is related to its length of time needed to orbit the sun • 3rd Law proves a mathematical pattern for laws 1 and 2 ...
... revolve around the sun once • Size of a planets orbit is related to its length of time needed to orbit the sun • 3rd Law proves a mathematical pattern for laws 1 and 2 ...
Pacing Our Solar System
... Pacing Our Solar System The chart below gives the scaled sizes and distances of the planets if the Sun were the size of a softball. Using these numbers, mark the distances in the model of planetary orbits, as instructed. One very large stride is roughly equal to a meter. As you can see, most of spac ...
... Pacing Our Solar System The chart below gives the scaled sizes and distances of the planets if the Sun were the size of a softball. Using these numbers, mark the distances in the model of planetary orbits, as instructed. One very large stride is roughly equal to a meter. As you can see, most of spac ...
Solar System Study Guide
... Saturn: A planet with 100s rings (made of dust, ice & rock), takes 29.5 years to orbit the Sun. Neptune: The beautiful blue/green planet (due to methane gas), strong winds (up to 1,300 mph), and takes 165 years to orbit the Sun. Uranus: The planet that spins on its side (horizontal), has many moons ...
... Saturn: A planet with 100s rings (made of dust, ice & rock), takes 29.5 years to orbit the Sun. Neptune: The beautiful blue/green planet (due to methane gas), strong winds (up to 1,300 mph), and takes 165 years to orbit the Sun. Uranus: The planet that spins on its side (horizontal), has many moons ...
Lecture2 - University of Waterloo
... • The true orbital period of the planet (sidereal period) tells how long it takes the planet to return to point P. • Observe the angles PES(initially) and PES (one superior planet period later). • The angle ESE’ is known from the Earth’s orbital period vs. the planets. And the triangles can be solv ...
... • The true orbital period of the planet (sidereal period) tells how long it takes the planet to return to point P. • Observe the angles PES(initially) and PES (one superior planet period later). • The angle ESE’ is known from the Earth’s orbital period vs. the planets. And the triangles can be solv ...
d = days y = years AU = astronomical unit Grade 6 Standard 3
... 8. The clouds that surround Venus are so thick that the planet actually absorbs less sunlight than the Earth. Nevertheless, Venus has a surface temperature of more than 400°C. Which of these best explains this high surface temperature? A. The bright surfaces of the clouds reflect sunlight back on t ...
... 8. The clouds that surround Venus are so thick that the planet actually absorbs less sunlight than the Earth. Nevertheless, Venus has a surface temperature of more than 400°C. Which of these best explains this high surface temperature? A. The bright surfaces of the clouds reflect sunlight back on t ...
Other objects in space guided notes
... • Debris left over from comets Meteorites • When a meteoroid is dragged towards by ___________________________________ and enters Earth atmosphere • Friction and atmosphere heats the object up and turns into a _____________________________ • Provide Clues from our Solar system Comets • Small, ______ ...
... • Debris left over from comets Meteorites • When a meteoroid is dragged towards by ___________________________________ and enters Earth atmosphere • Friction and atmosphere heats the object up and turns into a _____________________________ • Provide Clues from our Solar system Comets • Small, ______ ...
Flat Earth / Round Earth Activity
... Orbital Speeds: Planets with nearly circular orbits don’t show much variation in orbital speed, but the same is not true with comets or asteroids on highly elliptical orbits. Consider the orbit of Halley’s Comet shown at the top of the next page (eccentricity = 0.967). In this drawing the planets mo ...
... Orbital Speeds: Planets with nearly circular orbits don’t show much variation in orbital speed, but the same is not true with comets or asteroids on highly elliptical orbits. Consider the orbit of Halley’s Comet shown at the top of the next page (eccentricity = 0.967). In this drawing the planets mo ...
Kepler`s 3rd Law Applied to our Solar System
... First, let’s derive Kepler’s 3rd Law mathematically: In our Solar System, the planets are in elliptical orbits around the Sun (according to Kepler’s 1st Law), but the ellipses are very ...
... First, let’s derive Kepler’s 3rd Law mathematically: In our Solar System, the planets are in elliptical orbits around the Sun (according to Kepler’s 1st Law), but the ellipses are very ...
The kinematics of the Solar System
... we measure the angular diameter of planet to be θ, then its radius is r=θD/2 (D=distance to planet from Earth) Mass M of a planet is determined by applying Newton’s laws to either a satellite of the planet or a passing spacecraft Then the average density of the planet is ...
... we measure the angular diameter of planet to be θ, then its radius is r=θD/2 (D=distance to planet from Earth) Mass M of a planet is determined by applying Newton’s laws to either a satellite of the planet or a passing spacecraft Then the average density of the planet is ...
The Outer Planets - Spokane Public Schools
... so large all of the other planets could fit inside it. You could fit eleven Earths along its diameter and more than a thousand Earths inside it. Jupiter is made up of twice as much materials as all the outer planets put together. Jupiter is so big and bright that you can see it from Earth without a ...
... so large all of the other planets could fit inside it. You could fit eleven Earths along its diameter and more than a thousand Earths inside it. Jupiter is made up of twice as much materials as all the outer planets put together. Jupiter is so big and bright that you can see it from Earth without a ...
Why is Pluto no longer considered a planet?
... • It's smaller than any other planet – even smaller than the Earth's moon. • It's dense and rocky, like the terrestrial planets (Mercury, Venus, Earth and Mars). However, its nearest neighbors are the gaseous Jovian planets (Jupiter, Saturn, Uranus and Neptune). For this reason, many scientists beli ...
... • It's smaller than any other planet – even smaller than the Earth's moon. • It's dense and rocky, like the terrestrial planets (Mercury, Venus, Earth and Mars). However, its nearest neighbors are the gaseous Jovian planets (Jupiter, Saturn, Uranus and Neptune). For this reason, many scientists beli ...
8 planets in our solar system.
... in the opposite direction of the rest of the outer planets. It also has rings. Neptune is the farthest planet from the sun. It has narrow, faint rings arranged in clumps. ...
... in the opposite direction of the rest of the outer planets. It also has rings. Neptune is the farthest planet from the sun. It has narrow, faint rings arranged in clumps. ...
Venus is named after the Roman goddess of love and
... is two and a half times as massive as all the other planets in our Solar system combined.It has at least sixtyone moons and features the Great Red Spot, which is a huge "storm" that has been observed from here on Earth for over three hundred years. Jupiter is a gas planet so it is very extremely har ...
... is two and a half times as massive as all the other planets in our Solar system combined.It has at least sixtyone moons and features the Great Red Spot, which is a huge "storm" that has been observed from here on Earth for over three hundred years. Jupiter is a gas planet so it is very extremely har ...
Astronomy 100 -- Worksheet #7 THE JOVIAN PLANETS 1) The
... from the predictions following Newton’s Law of Gravity. If these deviations were due to the gravitational pull of an outer planet, the deviations in Neptune’s orbit could be used to calculate the location of the 9th planet. Unlike Neptune, however, searches for the 9th planet continued for 25 years ...
... from the predictions following Newton’s Law of Gravity. If these deviations were due to the gravitational pull of an outer planet, the deviations in Neptune’s orbit could be used to calculate the location of the 9th planet. Unlike Neptune, however, searches for the 9th planet continued for 25 years ...