A Brief History of Planetary Science

... Numbers are relative to the Earth ...

The Solar SysteM - Skyline R2 School

... The five planets farthest from the sun: Jupiter, Saturn, Uranus, Neptune, and Pluto ...

The Gas Planets

... in solar system •Has visible rings •Has 18 moons ...

Outer planets

... • Ganymede- largest moon in the Solar system • Callisto- more craters than any object in the Solar System ...

Our Solar System

... Served ...

Document

... Disk eventually cooled; different elements and compounds condensed depending on distance from sun Tiny grains of condensing material accumulated and collided; eventually formed planetismals (“baby planets”) Jupiter was the first large planet to form in outer ss; probably prevented other outer planet ...

Document

... What is the order of the planets? List the inner and outer planets? ...

Game

... What planet is very hot during the daytime and very cold at night due to its lack of atmosphere? ...

Solar System - Noadswood Science

... Solar System Presentations  To recap all the planets, and identify some of their key characteristics ...

2010_03_09 LP18 & 19 Jupiter Saturn Uranus

... first place? How do we know what the atmospheres are made of? How do we know that compounds are in an atmosphere, and not their components? Is/was there life on the giant planets or their moons? What makes the colors? Do the colors/stripes change over time? RINGS?!?!?!??!?!?!?! Temperature? ...

Solar system intro and formation

... Inner parts of disk hotter: mostly gas. Accretion of gas atoms onto dust grains relatively inefficient. Outer parts cooler: ices form (but still much gas), also ice "mantles" on dust grains => much more solid material for accretion => larger planetesimals => more gravity => even more material. Jovia ...

Solar System Formation

... • Large and low density • Lots of H compounds • Lots of satellites • Rings ...

Solar System Quiz

... ____ 18. Which of the following planets has seasons like Earth’s because its axis tilts at an almost identical angle? a. Venus c. Pluto b. Mercury d. Mars ____ 19. About 99% of all matter contained in the solar nebula now exists in a. space. c. asteroids. b. planets. d. the sun. ____ 20. Which of th ...

Impacts from space can form building blocks of life

... With Jupiter’s migration inward and Saturn’s outward as a result of gravitational jostling between gas giant planets shortly after the formation of the solar system, the disk of debris left from the sun’s formation had become unstable , unleashing a torrent of asteroids and comets onto the inner sol ...

Observational Astronomy - Lecture 7 Solar System II

... Trans-Neptunian Objects (TNOs) and the Kuiper belt. Comets and the Oort cloud. ...

Trans Neptunian Objects (TNOs)

... The 8 planets of the Solar System are clearly divided between the 4 inner, smaller, rocky planets and the 4 outer, much larger, gas planets. The inner planets orbit the Sun at faster speeds and within a two year period. Temperatures are warmer, being closer to the Sun and there are few moons (only t ...

Jupiter

... several bands at different latitudes, resulting in turbulence and storms along their interacting boundaries. A prominent result is the Great Red Spot, a giant storm that is known to have existed since at least the 17th century when it was first seen by telescope. ...

Real and Scaled Sizes of Dwarf Planets Ceres 930 km Pluto 2,370

... system represents 10 billion millimeters in the real solar system! Ceres is the largest object in the asteroid belt between Mars and Jupiter. The asteroid belt is the home of most, but not all, of the rocky asteroids in the solar system. Asteroids we can see from telescopes on Earth are about the si ...

Real and Scaled Sizes of Dwarf Planets Ceres 930 km 0.09 mm

... system represents 10 billion millimeters in the real solar system! Ceres is the largest object in the asteroid belt between Mars and Jupiter. The asteroid belt is the home of most, but not all, of the rocky asteroids in the solar system. Asteroids we can see from telescopes on Earth are about the si ...

The Gas Giant Planets

... Scientists think they are made of small, solid cores. Their interiors are fluid. Lightweight gases such as hydrogen and helium make up most of their mass. With all their satellites and ring systems, they are very interesting to observe. Jupiter is the largest planet. It is the fifth from the sun. Th ...

Comparing Earth, Sun and Jupiter

...  Gas and dust in the disk (total mass ~0.01 MSun) orbit the protostar in nearly circular orbits  However, the gas is also partially supported by pressure, so it orbits more slowly.  Thus, the dust grains feel a headwind of ~10 m/s due to the gas.  The smallest dust grains then orbit with the gas ...

the gas giants

... Jupiter is the largest planet. It is the fifth from the sun. The length of its year is about 4330 Earth days. This is how long it takes for Jupiter to make one revolution around the sun. It spins very fast, however. It takes only about nine Earth hours for Jupiter to make one rotation. Jupiter's dia ...

The Solar System consists of the Sun and the celestial objects

... The Solar System consists of the Sun and the celestial objects bound to it by gravity , all of which formed from the colapse of a giant molecular cloud aproximately 4,5 billions years ago. The Sun´s retinue of objects circle it in a nearly flat disc called the ecliptic plane, most of the mass of whi ...

Minor Bodies of the Solar System

... As a planet moves in its orbit, a line connecting the planet to the sun sweeps out equal areas in equal times ...

The affects of the Jovian planets

... off of larger objects in collisions. -These are pulled together by the strong gravitational pull of the planets • The Jovian Planets act as shields, protecting earth and other objects in the solar system from collisions. • However, They also posses the potential to “sling shot” a comet or other obje ...

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Jumping-Jupiter scenario

The jumping-Jupiter scenario specifies an evolution of giant-planet migration described by the Nice model, in which an ice giant (Uranus, Neptune, or an additional Neptune-mass planet) encounters first Saturn and then Jupiter, causing the step-wise separation of their orbits. The jumping-Jupiter scenario was proposed by Ramon Brasser, Alessandro Morbidelli, Rodney Gomes, Kleomenis Tsiganis, and Harold Levison after their studies revealed that the smooth divergent migration of Jupiter and Saturn resulted in an inner Solar System significantly different from the current Solar System. The sweeping of secular resonances through the inner Solar System during the migration excited the eccentricities of the terrestrial planets beyond current values and left an asteroid belt with an excessive ratio of high- to low-inclination objects. The step-wise separation of Jupiter and Saturn described in the jumping-Jupiter scenario allows these resonances to quickly cross the inner Solar System without altering orbits excessively. The jumping-Jupiter scenario also results in a number of other differences with the original Nice model. The fraction of lunar impactors from asteroid belt during the Late Heavy Bombardment is significantly reduced, most of the Jupiter trojans are captured via an alternative mechanism, and Jupiter acquires its population of irregular satellites via the same process as the other planets. The frequent ejection of an ice giant during simulations of the jumping-Jupiter scenario has led some to propose an additional giant planet in the early Solar System.

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Jumping-Jupiter scenario