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The concept of falling requires there to be something to fall onto/into and this something will have mass and a gravity field. The heaviness of the falling object is irrelevant, where there is no air to slow things, a feather will fall as fast as lead ball.
Thus all things in space are falling because gravity fields extend across the universe. For instance the planets of our solar system are falling round the Sun (when something is in orbit round something else, it is actually falling but it also has a sideways movement that means that it keeps missing the thing it is falling towards).
The Sun in turn is in orbit round the centre of our Milkyway Galaxy and our Galaxy is interacting graviometrically with the other galaxies in our local group and this in turn is interacting with our local supertcluster etc.
Thus the answer is yes BUT the heaviness of the object is irrelevant.
What else can I help you with?
Why do you fall in space instead of float?
In space, objects fall towards a massive body due to its gravitational pull. The absence of air resistance and other forces allows objects to continue falling indefinitely until they reach their destination. As a result, rather than floating, objects in space appear to be in a state of continuous free fall towards the center of gravity of the massive body they are near.
What travels through space and does not fall to earth?
Light travels through space and does not fall to Earth. It moves in a straight line, following the laws of physics, and does not get pulled down by gravity like objects with mass do.
How fast do objects go in free fallouter space?
Objects in free fall in outer space can reach very high speeds, limited only by the acceleration due to gravity and lack of air resistance. The speed depends on the gravitational force of the celestial body they are falling towards. For example, objects in free fall towards Earth's surface reach a speed of about 9.8 m/s².
Are objects in communications satellites weighless?
Objects in communication satellites still have weight, as weight is a measure of the force of gravity acting on an object. However, in the microgravity environment of space, objects appear weightless because they are in free fall around the Earth.
What happens when your in space?
In space, you experience microgravity, which means you feel weightless. Without gravity, you float around and objects don't fall to the ground. The lack of air and extreme temperatures can also affect how your body functions.
Do heavy objects fall to the ground before light objects?
In the absence of air resistance, heavy objects and light objects fall to the ground at the same rate. This is because all objects experience the same acceleration due to gravity, regardless of their mass. However, factors like air resistance can affect the rate at which objects fall.
What happens to objects that fall from space towards earth?
they all fall back into space like gravity.
What falls really fast?
Objects that fall really fast include heavy items like bowling balls or anvils, as they are less affected by air resistance compared to lighter objects. In a vacuum, all objects fall at the same rate regardless of their mass due to the absence of air resistance. Additionally, phenomena such as raindrops or meteorites can also fall quickly when influenced by gravity.
Aristotle said heavy objects will fall faster and Galileo said heavy and light objects will fall at the same acceleration?
Galileo's theory is more accurate - in a vacuum, objects of different weights will fall at the same rate. This principle is known as the equivalence principle. Aristotle's notion was based on observations in air where air resistance affects the fall rate of heavier objects.
Why do you fall off in space?
No gravity to weigh objects down
Why do objects all fall at the same time when gravity is the only force acting?
-- Because that's the way gravity behaves. -- Because is would be ridiculous to think that heavy objects fall faster. Here's why: ==> Let's say that heavy objects fall faster and light objects fall slower. ==> Take a piece of sticky tape and stick a light object onto the back of a heavy object. Then drop them together off of a roof. ==> The light object tries to fall slower and holds back, and the heavy object tries to fall faster and pulls forward. So when they're stuck together, they fall at some in-between speed. ==> But wait! When they're stuck together they weigh more than the heavy object alone. So how can a stuck-together object that's heavier than the heavy object alone fall at a speed that's slower than the heavy object alone ? ! ? Isn't that ridiculous ? There's no way that heavy objects can fall faster than light objects.
Why do thing fall at the same rate?
Because the gravity is the same. this does not explain why real heavy objects fall at the same rate as light ones since the more mass their is their is supposed to be more gravity.....also how does space/time warped space affect such things as the falling apple
Do all objects fall to the ground?
Objects fall to the ground due to gravity, which is a force that pulls objects toward each other. However, in microgravity environments like the International Space Station, objects appear to float because they are in constant free fall around the Earth.
Do all objets s fall?
No, not all objects fall. Only objects that are subject to gravity, like those on Earth's surface, will fall when not supported. Objects in space, for example, are in a state of free fall around a celestial body due to gravitational forces.
What objects in space are affected by the sun's gravity?
Such an object is said to be in free fall.
Who believed that heavy objects fall faster than lighter ones?
Aristotle believed that heavy objects fall faster than lighter ones. This idea was later proven wrong by Galileo's experiments, which showed that in a vacuum, objects of different weights fall at the same rate.
Why does a heavy object fall at the same rate as a light object in a vacuum?
In a vacuum, there is no air resistance to affect the rate at which objects fall. The acceleration due to gravity is the same for all objects regardless of their mass. Therefore, both a heavy object and a light object will fall at the same rate in a vacuum.
