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How could a satellite escape the gravitational pull of the Earth?

How could a satellite escape the gravitational pull of the Earth?

Satellites in circular orbit A satellite can be launched into orbit around Earth by accelerating it to a high tangential speed. If its speed is too high, the satellite will break free of Earth’s gravity and escape. If it is too low, it will fall back to Earth.

What happens when a satellite falls out of orbit?

If a satellite was 1,000 km (621 mi) above the Earth’s atmosphere, it might take over 100 years before it finally fell to the ground. So all these satellites falling to Earth would be a long, drawn-out process. Luckily for us, when they do finally fall on Earth, a lot of them will get burned up by our atmosphere.

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Do satellites affect gravity?

Only a small part of the rocket actually makes it into orbit. Assuming satellites are distributed more or less evenly around any given orbit, this also means the position of the centre of mass of Earth and its satellites doesn’t change, so Earth’s gravity with respect to the sun and moon isn’t affected.

How do satellites not fall?

Satellites don’t fall from the sky because they are orbiting Earth. Even when satellites are thousands of miles away, Earth’s gravity still tugs on them. Gravity–combined with the satellite’s momentum from its launch into space–cause the satellite go into orbit above Earth, instead of falling back down to the ground.

Can a satellite return to Earth?

The short answer is that most satellites don’t come back to Earth at all. Satellites are always falling towards the Earth, but never reaching it – that’s how they stay in orbit. They are meant to stay there, and usually there is no plan to bring them back to Earth.

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At what altitude does gravity end?

Near the surface of the Earth (sea level), gravity decreases with height such that linear extrapolation would give zero gravity at a height of one half of the Earth’s radius – (9.8 m·s−2 per 3,200 km.)