Other Planetary Systems
... …in many of the planetary systems detected so far, we find big, massive planets quite close to the parent stars (especially with the ‘wobble’ technique; using transits is better able to find smaller planets.) It will take many years, and improving technology, to allow the confirmed detection of a So ...
... …in many of the planetary systems detected so far, we find big, massive planets quite close to the parent stars (especially with the ‘wobble’ technique; using transits is better able to find smaller planets.) It will take many years, and improving technology, to allow the confirmed detection of a So ...
Earth ,Moon,and Sun - Laconia School District
... In addition to the earth rotating on its axis it also travels around the sun. This is called revolution. It is the movement of one object around another. One complete rotation around the sun is a year. Earth travels on its orbit or its path that leads it around the sun. Earth’s orbit is not quite a ...
... In addition to the earth rotating on its axis it also travels around the sun. This is called revolution. It is the movement of one object around another. One complete rotation around the sun is a year. Earth travels on its orbit or its path that leads it around the sun. Earth’s orbit is not quite a ...
PPT - osmaston.org.uk
... Counselman 1973 ApJ). Capture requires nebula present. 2. Tidal drag requires hot-viscous silicate planets, so only the 5-15 Me silicate ‘cores’ had been built (so Jupiter’s timescale problem is removed and metallic-H Jovian interior is untenable). 3. Tidal action cannot have provided their gas and ...
... Counselman 1973 ApJ). Capture requires nebula present. 2. Tidal drag requires hot-viscous silicate planets, so only the 5-15 Me silicate ‘cores’ had been built (so Jupiter’s timescale problem is removed and metallic-H Jovian interior is untenable). 3. Tidal action cannot have provided their gas and ...
lesson 1 Solar system - science
... Title: Describe long-term changes that have occurred in our universe to our solar system and earth ...
... Title: Describe long-term changes that have occurred in our universe to our solar system and earth ...
Review 1 - AST 1002 - FSU Physics Department
... How long would a star of 9 solar masses and 2700 solar luminosities remain on the main sequence? ...
... How long would a star of 9 solar masses and 2700 solar luminosities remain on the main sequence? ...
Chpt 27 Notes
... Cassini-Huygens is one of the most ambitious missions ever launched into space. Loaded with an array of powerful instruments and cameras, the spacecraft is capable of taking accurate measurements and detailed images in a variety of atmospheric conditions and light spectra. Two elements comprise ...
... Cassini-Huygens is one of the most ambitious missions ever launched into space. Loaded with an array of powerful instruments and cameras, the spacecraft is capable of taking accurate measurements and detailed images in a variety of atmospheric conditions and light spectra. Two elements comprise ...
Solar System - Legacy High School
... • The Solar System formed when a cold, slowlyrotating cloud of gas and dust collapsed because of its own gravity about 4.5 billion years ago. • As the Sun grew hot enough to ignite the nuclear reactions which sustain it today, it vaporized the cold ices and frozen gasses in the inner solar system, ...
... • The Solar System formed when a cold, slowlyrotating cloud of gas and dust collapsed because of its own gravity about 4.5 billion years ago. • As the Sun grew hot enough to ignite the nuclear reactions which sustain it today, it vaporized the cold ices and frozen gasses in the inner solar system, ...
Student Exploration Sheet: Growing Plants
... 2. Gather data: Select Mercury from the Solar system menu at left. Turn on Additional data. In the table below, record Mercury’s Mass, Mean radius, and Density. Then repeat for each of the other planets as well as the dwarf planet Pluto. Include units. Planet ...
... 2. Gather data: Select Mercury from the Solar system menu at left. Turn on Additional data. In the table below, record Mercury’s Mass, Mean radius, and Density. Then repeat for each of the other planets as well as the dwarf planet Pluto. Include units. Planet ...
16-6 How do astronomers measure distance?
... ____________________ 1. A light-year is equal to the distance that light travels in one day. ____________________ 2. One light-year is equal to a distance of about 10 trillion kilometers. ____________________ 3. An astronomical unit is equal to the distance between Earth and the Moon. ______________ ...
... ____________________ 1. A light-year is equal to the distance that light travels in one day. ____________________ 2. One light-year is equal to a distance of about 10 trillion kilometers. ____________________ 3. An astronomical unit is equal to the distance between Earth and the Moon. ______________ ...
SOL Study Book
... 3rd, Mars is 4th, Jupiter is 5th, Saturn is 6th, Uranus is 7th, and Neptune is 8th Memory Jogger: My Very Educated Mother Just Served Us Nachos 4. Sequence of Planets from largest to smallest: Jupiter, Saturn, Uranus, Neptune, Earth, Venus, Mars, and Mercury Memory Jogger: Jealous Sisters Usually Ne ...
... 3rd, Mars is 4th, Jupiter is 5th, Saturn is 6th, Uranus is 7th, and Neptune is 8th Memory Jogger: My Very Educated Mother Just Served Us Nachos 4. Sequence of Planets from largest to smallest: Jupiter, Saturn, Uranus, Neptune, Earth, Venus, Mars, and Mercury Memory Jogger: Jealous Sisters Usually Ne ...
Name____________________________________________________________________ Astronomy Packet 4
... as they got larger due to the force of __________. As the proto-planets grew they collected more and more material eventual resulting in a solar system with many small proto-planets the number was decreased as the proto-planets_________________ and ___________. It was one of these ______________ tha ...
... as they got larger due to the force of __________. As the proto-planets grew they collected more and more material eventual resulting in a solar system with many small proto-planets the number was decreased as the proto-planets_________________ and ___________. It was one of these ______________ tha ...
the earth and other planets
... Diameter =142.8X103km ~5.2AU from the sun Orbit =11.9 earth years 1 day =0.41 earth days ~61 moons; Ganymede is larger than Mercury; thin ring • Density =1.3g/ml • Gas giant planet mainly of Composite image of Jupiter by the Cassini probe. The black dot is the hydrogen and helium. shadow of Europa. ...
... Diameter =142.8X103km ~5.2AU from the sun Orbit =11.9 earth years 1 day =0.41 earth days ~61 moons; Ganymede is larger than Mercury; thin ring • Density =1.3g/ml • Gas giant planet mainly of Composite image of Jupiter by the Cassini probe. The black dot is the hydrogen and helium. shadow of Europa. ...
OUR PLANET EARTH
... • It is not a perfect sphere, it is flatted on the poles, because its north-south diametre is shorter than its east-west diametre. It is said that it has a geoid shape. • The elipsoid used to represent it has a maximum diametre of 12.756.776 km, and the minimum diametre of ...
... • It is not a perfect sphere, it is flatted on the poles, because its north-south diametre is shorter than its east-west diametre. It is said that it has a geoid shape. • The elipsoid used to represent it has a maximum diametre of 12.756.776 km, and the minimum diametre of ...
Solutions to test #1 taken on Monday
... replies: “As a matter of fact, black is an excellent color for heat. If you remember your blackbody radiation, black is actually best in heat. Efficient radiation.” Briefly describe why the mathematician, and by extension Michael Crichton, don’t know what they’re talking about and why it would reall ...
... replies: “As a matter of fact, black is an excellent color for heat. If you remember your blackbody radiation, black is actually best in heat. Efficient radiation.” Briefly describe why the mathematician, and by extension Michael Crichton, don’t know what they’re talking about and why it would reall ...
E1 Introduction to the Universe NEW
... Comets • Giant dirty snow balls (ice and dust) (diameter 100m - 50 km?) • Very elliptical orbits • Short period (T < 200 yrs) and long period (could be thousands of years) • Oort cloud • Tail(s) always point away from the sun • Evaporate as they get closer to the sun ...
... Comets • Giant dirty snow balls (ice and dust) (diameter 100m - 50 km?) • Very elliptical orbits • Short period (T < 200 yrs) and long period (could be thousands of years) • Oort cloud • Tail(s) always point away from the sun • Evaporate as they get closer to the sun ...
Spring 2013 Final Exam Study Guide
... 42. Which layer of the sun is considered the surface? 43. Which layer of the sun gives it its color? 44. In which layer of the sun does it produce its energy? 45. What is the process called that produces the Sun’s energy? 46. What gas is used to make the energy in the Sun? 47. What gas is produced w ...
... 42. Which layer of the sun is considered the surface? 43. Which layer of the sun gives it its color? 44. In which layer of the sun does it produce its energy? 45. What is the process called that produces the Sun’s energy? 46. What gas is used to make the energy in the Sun? 47. What gas is produced w ...
ppt - The Eclecticon of Dr French
... ancestors. These constellations are of course in motion within the Milky way galaxy, so are not fixed! ...
... ancestors. These constellations are of course in motion within the Milky way galaxy, so are not fixed! ...
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.