Smoke some weed
No, its depends on the planets gravitational pull
The Jovian planets have much higher escape velocities.
Escape velocity is the minimum speed that an object must reach to break free from the gravitational pull of a celestial body. This velocity allows the object to overcome the body's gravitational force and enter into space. The specific value of escape velocity depends on the mass and radius of the celestial body.
That will depend not only on the escape velocity, but also - very importantly - on the object's speed.
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.
Yes. It is different for different planets etc. Escape velocity on earth is different than escape velocity on Jupiter.
Escape Velocity
Yes. Probes have already be sent to the Moon, and other planets; this requires a velocity very near the escape velocity from Earth. Other probes are leaving the Solar System, so they achieved the much higher escape velocity required to escape the attraction from the Sun.
What is the Earth's escape velocity in km/sec
It depends on the planet.
No, its depends on the planets gravitational pull
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.
Jupiter has the greatest escape velocity in our solar system, due to its large mass and strong gravitational pull. The escape velocity on Jupiter is about 59.5 km/s, which is higher than any other planet in our solar system.
Assuming there is no air resistance, if an object starts at a speed of 11.2 km/sec, it can escape the gravitational field of Earth. This "escape velocity" is different for different planets, moons, etc.Assuming there is no air resistance, if an object starts at a speed of 11.2 km/sec, it can escape the gravitational field of Earth. This "escape velocity" is different for different planets, moons, etc.Assuming there is no air resistance, if an object starts at a speed of 11.2 km/sec, it can escape the gravitational field of Earth. This "escape velocity" is different for different planets, moons, etc.Assuming there is no air resistance, if an object starts at a speed of 11.2 km/sec, it can escape the gravitational field of Earth. This "escape velocity" is different for different planets, moons, etc.
the gas giant planets have strong gravitational pulls that hold on to their thick atmospheres. Additionally, the high escape velocity prevents the gases from escaping into space. The cold temperatures of these planets also help in maintaining the integrity of their atmospheres.
Escape Velocity Override happened in 1998.
Escape Velocity Override was created in 1998.