Lecture notes -
... The unit for interplanetary distances: the Astronomical Unit • Average distance between the Earth and Sun • The astronomical unit = 149,600,000 km • In scientific notation: • The AU = 93,000,000 miles • The AU is 17 years in an economy ...
... The unit for interplanetary distances: the Astronomical Unit • Average distance between the Earth and Sun • The astronomical unit = 149,600,000 km • In scientific notation: • The AU = 93,000,000 miles • The AU is 17 years in an economy ...
The Solar System - Academic Resources at Missouri Western
... Small in size Irregular in shape ...
... Small in size Irregular in shape ...
Life: Definition, Origin, Criteria
... billions of years • Less than 1.5 times massive than the Sun; otherwise too much UV • More than 0.3 times the mass of the Sun; large warm region near the star for liquid water • Limited to no more than 10 billion stars ...
... billions of years • Less than 1.5 times massive than the Sun; otherwise too much UV • More than 0.3 times the mass of the Sun; large warm region near the star for liquid water • Limited to no more than 10 billion stars ...
Exam 2 Review – Earth in Space, Atmosphere
... of Mercury’s mantle, retrograde rotation of Venus, extreme axial tilt of Uranus Rearrangement of orbits of outer planets, perturbation of the asteroid belt, icy asteroids / comets as a source of water in the inner Solar System Sun – source of energy (fusion of hydrogen to helium), evolution from mai ...
... of Mercury’s mantle, retrograde rotation of Venus, extreme axial tilt of Uranus Rearrangement of orbits of outer planets, perturbation of the asteroid belt, icy asteroids / comets as a source of water in the inner Solar System Sun – source of energy (fusion of hydrogen to helium), evolution from mai ...
Life: Definition, Origin, Criteria
... • Planets should form naturally out of stellar ‘debris’ in the disk • We can now detect many planets, from Jupiter to Earth size ...
... • Planets should form naturally out of stellar ‘debris’ in the disk • We can now detect many planets, from Jupiter to Earth size ...
Life: Definition, Origin, Criteria
... • Planets should form naturally out of stellar ‘debris’ in the disk • We can now detect many planets, from Jupiter to Earth size ...
... • Planets should form naturally out of stellar ‘debris’ in the disk • We can now detect many planets, from Jupiter to Earth size ...
1 DS 3.10 Grade 9 Review
... 14. What is nuclear fusion? 15. What does the colour of a star indicate? 16. What is a galaxy? 17. Name our galaxies and the group it is part of. 18. Describe 3 galaxy shapes. 19. Describe the 3 main stages of the formation of the solar system. 20. Explain the term red shift. What does this indicate ...
... 14. What is nuclear fusion? 15. What does the colour of a star indicate? 16. What is a galaxy? 17. Name our galaxies and the group it is part of. 18. Describe 3 galaxy shapes. 19. Describe the 3 main stages of the formation of the solar system. 20. Explain the term red shift. What does this indicate ...
Our Solar System - After School Astronomy Clubs
... Jupiter, the fifth planet from the Sun, is the largest planet in our solar system. Jupiter is so big that over 1,000 planets the size of Earth could fit into it. It has over 60 moons and 2 rings. Can life exist on Jupiter's moon, Europa? ...
... Jupiter, the fifth planet from the Sun, is the largest planet in our solar system. Jupiter is so big that over 1,000 planets the size of Earth could fit into it. It has over 60 moons and 2 rings. Can life exist on Jupiter's moon, Europa? ...
Document
... *** The third method is based on detecting the small drop in apparent luminosity of a star as a planet transits in front of it, between the star and the Earth. ...
... *** The third method is based on detecting the small drop in apparent luminosity of a star as a planet transits in front of it, between the star and the Earth. ...
Slides
... flattened out into a “protoplanetary disc” with a diameter of 200 au, which would latter form the planets, moons and asteroids. The protoplanetary disc became thinner and thinner as the proto star pulled in more matter. Eventually particles in this disc began clumping. These clumps continued to ad ...
... flattened out into a “protoplanetary disc” with a diameter of 200 au, which would latter form the planets, moons and asteroids. The protoplanetary disc became thinner and thinner as the proto star pulled in more matter. Eventually particles in this disc began clumping. These clumps continued to ad ...
Solar System
... Solar System Notes – Part 1 Universe: all of space and ________________________________________________ Galaxy: A large group of __________________________________, solar systems, and associated gas and dust in space that is bound by _____________________________ Solar System: Composed of one ...
... Solar System Notes – Part 1 Universe: all of space and ________________________________________________ Galaxy: A large group of __________________________________, solar systems, and associated gas and dust in space that is bound by _____________________________ Solar System: Composed of one ...
Earth Science SOL Review Sheet #1
... The sun is made of mostly hydrogen gas and its energy comes from nuclear fusion reactions. Mercury, Venus, Earth and Mars are terrestrial planets. Jupiter, Saturn, Uranus and Neptune are gas giants. The asteroid belt is located between Mars and Jupiter. Made of ice and frozen gases, comets als ...
... The sun is made of mostly hydrogen gas and its energy comes from nuclear fusion reactions. Mercury, Venus, Earth and Mars are terrestrial planets. Jupiter, Saturn, Uranus and Neptune are gas giants. The asteroid belt is located between Mars and Jupiter. Made of ice and frozen gases, comets als ...
Astronomy HOMEWORK Chapter 8
... maintains the Cassini division from a distance by gravitational resonance. 26. Explain why Triton will never collide with Neptune, even though it is spiraling toward that Planet. Triton will be torn apart by tidal stresses before it collides. It will then form a prominent ring system. 37. What IF: J ...
... maintains the Cassini division from a distance by gravitational resonance. 26. Explain why Triton will never collide with Neptune, even though it is spiraling toward that Planet. Triton will be torn apart by tidal stresses before it collides. It will then form a prominent ring system. 37. What IF: J ...
The Solar System
... The 8 Planets of Our Solar System Mercury Venus Earth Mars Jupiter Saturn Uranus Neptune ...
... The 8 Planets of Our Solar System Mercury Venus Earth Mars Jupiter Saturn Uranus Neptune ...
Solar System Unit Review - Parma City School District
... • B. More stars are in the center than on the outer edge. • C. Most of the stars are near the outside of the galaxy. • D. The stars are spread throughout the galaxy in bands ...
... • B. More stars are in the center than on the outer edge. • C. Most of the stars are near the outside of the galaxy. • D. The stars are spread throughout the galaxy in bands ...
ASTRO REVIEW 14
... _____ 8. Which object has such a strong surface gravity that light cannot escape it? a. super nova b. red giant c. black hole d. nebula _____ 9. What theory states that the universe began in a violent explosion? a. Doppler effect b. big crunch c. big bang d. Hubble’s law 10. Compare and contrast the ...
... _____ 8. Which object has such a strong surface gravity that light cannot escape it? a. super nova b. red giant c. black hole d. nebula _____ 9. What theory states that the universe began in a violent explosion? a. Doppler effect b. big crunch c. big bang d. Hubble’s law 10. Compare and contrast the ...
Formation and evolution of the Solar System
The formation of the Solar System began 4.6 billion years ago with the gravitational collapse of a small part of a giant molecular cloud. Most of the collapsing mass collected in the center, forming the Sun, while the rest flattened into a protoplanetary disk out of which the planets, moons, asteroids, and other small Solar System bodies formed.This widely accepted model, known as the nebular hypothesis, was first developed in the 18th century by Emanuel Swedenborg, Immanuel Kant, and Pierre-Simon Laplace. Its subsequent development has interwoven a variety of scientific disciplines including astronomy, physics, geology, and planetary science. Since the dawn of the space age in the 1950s and the discovery of extrasolar planets in the 1990s, the model has been both challenged and refined to account for new observations.The Solar System has evolved considerably since its initial formation. Many moons have formed from circling discs of gas and dust around their parent planets, while other moons are thought to have formed independently and later been captured by their planets. Still others, such as the Moon, may be the result of giant collisions. Collisions between bodies have occurred continually up to the present day and have been central to the evolution of the Solar System. The positions of the planets often shifted due to gravitational interactions. This planetary migration is now thought to have been responsible for much of the Solar System's early evolution.In roughly 5 billion years, the Sun will cool and expand outward many times its current diameter (becoming a red giant), before casting off its outer layers as a planetary nebula and leaving behind a stellar remnant known as a white dwarf. In the far distant future, the gravity of passing stars will gradually reduce the Sun's retinue of planets. Some planets will be destroyed, others ejected into interstellar space. Ultimately, over the course of tens of billions of years, it is likely that the Sun will be left with none of the original bodies in orbit around it.