Table of Contents
What planet has the strongest force?
Jupiter has the highest amount of gravity in our solar system. Jupiter is the largest in our Solar System, meaning it also has the highest gravity. You would weigh two and a half times on Jupiter than what you would on Earth.
What planet gives off the most energy?
Saturn
The planet that shines the most, relative to its size, is Saturn, but Jupiter and Neptune also radiate significantly more energy than they receive. Uranus, an odd planet in many ways, shines the least of all the solar system’s outer worlds, emitting about as much energy as Earth.
Which planet has the shortest year?
Mercury
Fastest Planet The closer a planet is to the Sun, the faster it travels. Since Mercury is the fastest planet and has the shortest distance to travel around the Sun, it has the shortest year of all the planets in our solar system – 88 days.
Which is planet would a spaceship need the largest force to?
The force of planetary attraction toward the sun would increase, the planet velocity would increase and the planets would be become smaller from the gravitational compressive force on each planet. Where would you do if you could travel in a spaceship?
Which is the planet with the least eccentricity?
Eccentricity is the measure of the “roundness” of an orbit. A perfectly circular orbit has an eccentricity of zero; higher numbers indicate more elliptical orbits. Neptune, Venus, and Earth are the planets in our solar system with the least eccentric orbits. Mercury and the dwarf planet Pluto have the most eccentric orbits.
Which is stronger the gravitational pull of the sun or the planet?
The closer a planet is to the Sun, the stronger the Sun’s gravitational pull on it, and the faster the planet moves. The farther it is from the Sun, the weaker the Sun’s gravitational pull, and the slower it moves in its orbit. Kepler’s Third Law Compares the Motion of Objects in Orbits of Different Sizes
Why is the core of a planet subject to high pressure?
Regarding the ‘core’ scenario, the core of a planet is subject to ludicrously high pressure due to the gravitational attraction of its constituent matter. To significantly shift any amount of material near or at the core of a planet would require a force at least equal to that pressure x the area over which it would be applied.