That would be its escape velocity.
Escape velocity is what a moving body has to achieve in order not to be pulled back down to the planet. For Earth it is about 7 miles per second.
An object with mass might approach, but never reach, the speed of light.An object with mass might approach, but never reach, the speed of light.An object with mass might approach, but never reach, the speed of light.An object with mass might approach, but never reach, the speed of light.
That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.
Escape velocity is the velocity that an object needs in order to reach infinite distance, wherein the force will equal to zero. Orbital velocity is the velocity of an object so it can stay in orbit.
The escape velocity from Earth is 11.2 kilometers/second. This is also the speed that an object would reach if it fell onto Earth's surface from far, far away ("infinity" is often used, to simplify calculations) - without air resistance, and without interference by other objects that might also attract it.The escape velocity from Earth is 11.2 kilometers/second. This is also the speed that an object would reach if it fell onto Earth's surface from far, far away ("infinity" is often used, to simplify calculations) - without air resistance, and without interference by other objects that might also attract it.The escape velocity from Earth is 11.2 kilometers/second. This is also the speed that an object would reach if it fell onto Earth's surface from far, far away ("infinity" is often used, to simplify calculations) - without air resistance, and without interference by other objects that might also attract it.The escape velocity from Earth is 11.2 kilometers/second. This is also the speed that an object would reach if it fell onto Earth's surface from far, far away ("infinity" is often used, to simplify calculations) - without air resistance, and without interference by other objects that might also attract it.
Escape Velocity
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 what a moving body has to achieve in order not to be pulled back down to the planet. For Earth it is about 7 miles per second.
The fastest velocity a falling object can reach is called its terminal velocity. This happens when the force of air resistance is equal to the downwards force of weight (gravity), so the object is in equilibrium, and thus reaches a constant velocity.
This is referred to as the escape velocity. This is the speed that an object must reach in order to overcome the gravitational pull of the planet to make it into space.
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.
When on Earth, you can escape if you move away from the Earth at the "escape" speed. Gravity will slow you down and you will reach zero speed at an infinite distance.
An object with mass might approach, but never reach, the speed of light.An object with mass might approach, but never reach, the speed of light.An object with mass might approach, but never reach, the speed of light.An object with mass might approach, but never reach, the speed of light.
Quasar
That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.
Escape velocity is the velocity that an object needs in order to reach infinite distance, wherein the force will equal to zero. Orbital velocity is the velocity of an object so it can stay in orbit.
None. Their had only reach the moon.