Introduction to the Solar System
... Mercury and Venus are inferior planets - that is, they are nearer the Sun than the Earth. The superior planets are those which are further away from the Sun than Earth. They are Mars, Jupiter, Saturn, Uranus and Neptune. Is there anything else going around the Sun? Yes, there is a miscellaneous coll ...
... Mercury and Venus are inferior planets - that is, they are nearer the Sun than the Earth. The superior planets are those which are further away from the Sun than Earth. They are Mars, Jupiter, Saturn, Uranus and Neptune. Is there anything else going around the Sun? Yes, there is a miscellaneous coll ...
summ assess astro sci 8 20152016
... c) Gravitational force gets weaker as the distance increases between masses d) Gravitational force depends on the size of the masses 10. What is the best explanation for why we can see Mercury, Venus, Mars, Jupiter, and Saturn without a telescope but cannot see Uranus, Neptune, and Pluto. a) The res ...
... c) Gravitational force gets weaker as the distance increases between masses d) Gravitational force depends on the size of the masses 10. What is the best explanation for why we can see Mercury, Venus, Mars, Jupiter, and Saturn without a telescope but cannot see Uranus, Neptune, and Pluto. a) The res ...
The Solar System (Planetary Debris) - NATSCI-A7
... and metals that orbit around the Sun. They are also called planetoids • planetary debris made up of chunks of rocks and metals that orbit around the Sun. They are also called planetoids • compose only a fraction of the Solar System ...
... and metals that orbit around the Sun. They are also called planetoids • planetary debris made up of chunks of rocks and metals that orbit around the Sun. They are also called planetoids • compose only a fraction of the Solar System ...
Our Solar system - Northwest Arkansas Community College
... Neptune • Neptune has visual belts of clouds • Just like Jupiter it has storms happening all around the planet • It has a dark blue spot • Neptune is the farthest planet from the Sun ...
... Neptune • Neptune has visual belts of clouds • Just like Jupiter it has storms happening all around the planet • It has a dark blue spot • Neptune is the farthest planet from the Sun ...
Name_________________________ 1 AST 101 Ancient
... Note: the phases of Venus showed that it was moving around the Sun and do NOT address any specific objections to Kepler’s model ...
... Note: the phases of Venus showed that it was moving around the Sun and do NOT address any specific objections to Kepler’s model ...
Spaceship Earth
... • Small variation for Earth — about 3% • Distance does matter for some other planets, notably Mars and Pluto. • Surprisingly, seasons are more extreme in N. hemisphere, even thought Earth is closer to Sun in S. hemisphere summer (and farther in S. hemisphere winter) because of land/ocean distributio ...
... • Small variation for Earth — about 3% • Distance does matter for some other planets, notably Mars and Pluto. • Surprisingly, seasons are more extreme in N. hemisphere, even thought Earth is closer to Sun in S. hemisphere summer (and farther in S. hemisphere winter) because of land/ocean distributio ...
Solar System Test Review - Clearview Local Schools
... A student rubs two wooden sticks together very hard and fast. What effect will this rubbing have? A. The sticks will begin to melt B. The sticks will become magnetic C. The temperature of the sticks will increase ...
... A student rubs two wooden sticks together very hard and fast. What effect will this rubbing have? A. The sticks will begin to melt B. The sticks will become magnetic C. The temperature of the sticks will increase ...
Origin of the Solar System ppt
... • The strong wind from the young Sun cleared excess gas from the solar nebula, but many planetesimals remained scattered between the newly formed planets. • These leftovers became the comets and ...
... • The strong wind from the young Sun cleared excess gas from the solar nebula, but many planetesimals remained scattered between the newly formed planets. • These leftovers became the comets and ...
The Inner Planets - Germantown School District
... the surface you would be quickly crushed by the weight of its atmosphere; pressure is 90 times greater than the pressure of Earth’s atmosphere; you couldn’t breathe on Venus because its atmosphere is mostly carbon dioxide Rotation- takes about 7.5 Earth months to revolve around the sun and 8 months ...
... the surface you would be quickly crushed by the weight of its atmosphere; pressure is 90 times greater than the pressure of Earth’s atmosphere; you couldn’t breathe on Venus because its atmosphere is mostly carbon dioxide Rotation- takes about 7.5 Earth months to revolve around the sun and 8 months ...
The Origin of Our Solar System Part 1 Survey of the solar system
... • Vredefort , Free State, South Africa, 300km diameter, 2023 millions of years old • Sudbury Ontario, Canada, 250 km diameter, 1849 million years old • Chicxulub, Yucatán, Mexico, 180 km diameter, 65 million years old • Kara, Nenetsia, Russia 120 km, 70.3 million years old. • Manicouagan, Quebec, Ca ...
... • Vredefort , Free State, South Africa, 300km diameter, 2023 millions of years old • Sudbury Ontario, Canada, 250 km diameter, 1849 million years old • Chicxulub, Yucatán, Mexico, 180 km diameter, 65 million years old • Kara, Nenetsia, Russia 120 km, 70.3 million years old. • Manicouagan, Quebec, Ca ...
The Mystery of Mars - Open Court Resources.com
... plant from the extreme conditions in space. Earth’s atmosphere contains mostly oxygen, whereas Mars’s contains mostly carbon dioxide. ...
... plant from the extreme conditions in space. Earth’s atmosphere contains mostly oxygen, whereas Mars’s contains mostly carbon dioxide. ...
Motions of the Planets: Not the same as Stars!
... • Mars, Jupiter, Saturn: move eastward within the zodiac, but each one makes a westward loop once a year when its farthest from the sun • Uranus, Neptune: need a telescope to see them, bu they each describe westward loops once a year, each smaller than the previous planet. How can this motion be ex ...
... • Mars, Jupiter, Saturn: move eastward within the zodiac, but each one makes a westward loop once a year when its farthest from the sun • Uranus, Neptune: need a telescope to see them, bu they each describe westward loops once a year, each smaller than the previous planet. How can this motion be ex ...
ppt
... • Mars, Jupiter, Saturn: move eastward within the zodiac, but each one makes a westward loop once a year when its farthest from the sun •Uranus, Neptune: need a telescope to see them, bu they each describe westward loops once a year, each smaller than the previous planet. How can this motion be expl ...
... • Mars, Jupiter, Saturn: move eastward within the zodiac, but each one makes a westward loop once a year when its farthest from the sun •Uranus, Neptune: need a telescope to see them, bu they each describe westward loops once a year, each smaller than the previous planet. How can this motion be expl ...
HERE
... 14. What is the term for the openings in the Earth from which magma is ejected? 15. Where are 75% of the Earth’s volcanoes located? Mark A if the statement is true; Mark B if the statement is false. 16. The epicenter of an earthquake is directly ABOVE the focus. 17. Fossils are found in igneous rock ...
... 14. What is the term for the openings in the Earth from which magma is ejected? 15. Where are 75% of the Earth’s volcanoes located? Mark A if the statement is true; Mark B if the statement is false. 16. The epicenter of an earthquake is directly ABOVE the focus. 17. Fossils are found in igneous rock ...
Warm Up - Cloudfront.net
... • Brahe’s observations, especially of Mars, were far more precise than any made previously • Brahe’s assistant, Johannes Kepler, kept most of Brahe’s observations and put them to exceptional use ...
... • Brahe’s observations, especially of Mars, were far more precise than any made previously • Brahe’s assistant, Johannes Kepler, kept most of Brahe’s observations and put them to exceptional use ...
Planet formation
... dust and ice with a central star. • As the disk picks up rotational speed it’s diameter gets smaller and more dense. ...
... dust and ice with a central star. • As the disk picks up rotational speed it’s diameter gets smaller and more dense. ...
GEOMORPHOLOGY
... SIMA – Silica and Continental crust 5 – 70km Magnesium Approximately 2800km Mainly solid rock, but may 1000°C become “plastic” in nature as rocks start to melt Approximately 2200km ...
... SIMA – Silica and Continental crust 5 – 70km Magnesium Approximately 2800km Mainly solid rock, but may 1000°C become “plastic” in nature as rocks start to melt Approximately 2200km ...
The Solar System – Gravity, Orbits, Comets, Asteroids and Meteors
... Learning Target #2 – I can explain how our understanding of the solar system developed through the contributions of the following astronomers: Ptolemy, Copernicus, Galileo, Kepler, and Newton. Learning Target #3 – I can tell the difference between the two models of the solar system. Learning Target ...
... Learning Target #2 – I can explain how our understanding of the solar system developed through the contributions of the following astronomers: Ptolemy, Copernicus, Galileo, Kepler, and Newton. Learning Target #3 – I can tell the difference between the two models of the solar system. Learning Target ...
INTRODUCTION
... Recently another body was discovered to be orbiting the sun. This object, called a “Planetoid” is about ¾ the size of Pluto and has a very elongated orbit that takes it as far as 81 billion miles form the sun. This planetoid has been named Sedna. ...
... Recently another body was discovered to be orbiting the sun. This object, called a “Planetoid” is about ¾ the size of Pluto and has a very elongated orbit that takes it as far as 81 billion miles form the sun. This planetoid has been named Sedna. ...
Mission 1 Glossary
... to plan, record and control the movement of a ship or plane Moon - can be any natural object orbiting around another; often refers to the Moon of the Earth (but other planets have moons too.) The Moon of the Earth was probably formed when a large object struck the Earth a long time ago. ...
... to plan, record and control the movement of a ship or plane Moon - can be any natural object orbiting around another; often refers to the Moon of the Earth (but other planets have moons too.) The Moon of the Earth was probably formed when a large object struck the Earth a long time ago. ...
Late Heavy Bombardment
The Late Heavy Bombardment (abbreviated LHB and also known as the lunar cataclysm) is a hypothetical event thought to have occurred approximately 4.1 to 3.8 billion years (Ga) ago, corresponding to the Neohadean and Eoarchean eras on Earth. During this interval, a disproportionately large number of asteroids apparently collided with the early terrestrial planets in the inner Solar System, including Mercury, Venus, Earth, and Mars. The LHB happened after the Earth and other rocky planets had formed and accreted most of their mass, but still quite early in Earth's history.Evidence for the LHB derives from lunar samples brought back by the Apollo astronauts. Isotopic dating of Moon rocks implies that most impact melts occurred in a rather narrow interval of time. Several hypotheses are now offered to explain the apparent spike in the flux of impactors (i.e. asteroids and comets) in the inner Solar System, but no consensus yet exists. The Nice model is popular among planetary scientists; it postulates that the gas giant planets underwent orbital migration and scattered objects in the asteroid and/or Kuiper belts into eccentric orbits, and thereby into the path of the terrestrial planets. Other researchers argue that the lunar sample data do not require a cataclysmic cratering event near 3.9 Ga, and that the apparent clustering of impact melt ages near this time is an artifact of sampling materials retrieved from a single large impact basin. They also note that the rate of impact cratering could be significantly different between the outer and inner zones of the Solar System.