Wiki User
∙ 13y agoNo, its depends on the planets gravitational pull
Wiki User
∙ 13y agoThe escape velocity of a planet depends on its mass and radius. Density does not directly affect the escape velocity, but it can impact the overall gravitational pull of the planet.
Yes, escape velocity does depend on the height from which an object is projected. The higher the height, the lower the escape velocity required because the gravitational force weakens with distance from the center of the planet.
The escape velocity of Jupiter is approximately 133,322 miles per hour. This is the speed at which an object must travel to break free from Jupiter's gravitational pull and escape into space.
The greater the mass of the planet, the greater will be the escape velocity.
Hydrogen probably cannot exist for a long time on Mars. As you suggest this is because of the planet's fairly low gravity and escape velocity. It's easier for a very light atom or molecule, such as hydrogen, to reach the planet's escape velocity, caused by collisions in the atmosphere.
The escape velocity of Mercury is about 4.3 km/s, which is the speed an object must reach to break free from Mercury's gravitational pull and move into space.
"Escape velocity" is defined as the velocity required in order to guarantee that the object will not fall back under the influence of the planet's gravitational attraction. If it's possible to escape from a planet's gravitational attraction, then an escape velocity can be defined and calculated.
The escape velocity is determined by the gravity of the planet which in turn is determined by the mass and size of the planet
To escape from a planet's gravitational pull, an object must reach a speed called the "escape velocity." This velocity depends on the mass and radius of the planet from which the object is trying to escape.
The escape velocity of Jupiter is approximately 133,322 miles per hour. This is the speed at which an object must travel to break free from Jupiter's gravitational pull and escape into space.
Yes, escape velocity does depend on the height from which an object is projected. The higher the height, the lower the escape velocity required because the gravitational force weakens with distance from the center of the planet.
The simple answer is that unless the rocket achieves escape velocity, the planet it hits would be Mars. Due to the rotation of the planets, if it did reach escape velocity, it would depend on the position of the planets and the path into space it took.
Escape velocity is the minimum velocity needed for an object to break free from the gravitational pull of a celestial body, such as a planet or moon. It allows an object to overcome gravity and travel into space without being pulled back. The specific escape velocity depends on the mass and radius of the celestial body.
The greater the mass of the planet, the greater will be the escape velocity.
It depends on the planet.
The escape velocity of Charon, the largest moon of Pluto, is about 550 meters per second. This is the minimum velocity an object must have to overcome Charon's gravitational pull and escape into space.
Escape velocity is given by. √2gR or √2GM/R .therefore escape velocity is directly prop. to gravity of a planet or star or any other body. More is the gravity more is the escape velocity. The escape velocity of our earth is 11.2 km/s and that of moon is 2.31 km/s
Different planets have different escape speeds due to variations in their gravitational pull. A planet with a higher mass will have a higher escape speed, as the force of gravity is stronger. Escape speed is the velocity needed to break free from a planet's gravitational field and overcome the gravitational pull.