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Yes. And objects with different sizes, masses, and weights also fall the same.

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Does the size of an object affect the time of its free fall?

No, the size of an object does not affect the time of its free fall. In a vacuum, all objects fall at the same rate regardless of their size or mass, as described by the principle of equivalence in the theory of general relativity. This means that in the absence of air resistance, objects of different sizes will reach the ground at the same time when dropped from the same height.


How does ball size affect the time it takes the ball to fall?

The size of a ball does not directly affect the time it takes to fall in the absence of air resistance. In a vacuum, all objects would fall at the same rate regardless of size. This is known as the principle of acceleration due to gravity.


Do things fall at the same speed?

Well it really depends on several factors that have to be just right in order for two objects to fall at the same speed or rate.The three main factors needed to calculate the speed at which two objects fall are Time(t) Velocity(v) and Rate of Acceleration.The formula used to calculate is:Acceleration= v-u/t (the v-u is change in velocity)The reason different objects accelerate the same (when you can ignore air resistance!) is because an object with more mass has more weight, but it also has more inertia.


Does the size of the ball effect how fast it falls?

Everything falls at the same speed. the only variable is drag. For instance a feather & a bowling ball would fall at the same speed in a vacuum, but not through the air.


Why are is the acceleration due to gravity the same for all objects?

The acceleration due to gravity is the same for all objects because it depends only on the mass of the Earth and the distance from its center, and not on the objects' mass or composition. This means that all objects, regardless of their size or weight, fall towards the Earth at the same rate of 9.8 m/s^2 (on the surface of the Earth).

Related Questions

Does the size of an object affect the time of its free fall?

No, the size of an object does not affect the time of its free fall. In a vacuum, all objects fall at the same rate regardless of their size or mass, as described by the principle of equivalence in the theory of general relativity. This means that in the absence of air resistance, objects of different sizes will reach the ground at the same time when dropped from the same height.


Will objects of different mass but the same size and shape fall at the same rate?

In the absence of any other force on them other than the force of gravity, all objects, regardless of their mass, size, shape, density, color, creed, or religious, political, or gender affiliation, fall with the same acceleration. That means that with equal initial velocities, their velocities are all the same after falling for equal times.


Do objects of different weights but similar size and shape fall to the ground at the same rate?

Yes. In the absence of air, it doesn't even matter how their shapes and sizes compare.


Do heavier objects fall faster than lighter objects when on a parachute?

Assuming the parachutes are the same size, then yes.


How does ball size affect the time it takes the ball to fall?

The size of a ball does not directly affect the time it takes to fall in the absence of air resistance. In a vacuum, all objects would fall at the same rate regardless of size. This is known as the principle of acceleration due to gravity.


Do things fall at the same speed?

Well it really depends on several factors that have to be just right in order for two objects to fall at the same speed or rate.The three main factors needed to calculate the speed at which two objects fall are Time(t) Velocity(v) and Rate of Acceleration.The formula used to calculate is:Acceleration= v-u/t (the v-u is change in velocity)The reason different objects accelerate the same (when you can ignore air resistance!) is because an object with more mass has more weight, but it also has more inertia.


Does the size of the ball effect how fast it falls?

Everything falls at the same speed. the only variable is drag. For instance a feather & a bowling ball would fall at the same speed in a vacuum, but not through the air.


Why are is the acceleration due to gravity the same for all objects?

The acceleration due to gravity is the same for all objects because it depends only on the mass of the Earth and the distance from its center, and not on the objects' mass or composition. This means that all objects, regardless of their size or weight, fall towards the Earth at the same rate of 9.8 m/s^2 (on the surface of the Earth).


Why did the flat sheet of paper fall at the same rate as the book?

If that's what actually happened, then you must have done the experiment either in a vacuum chamber or else on the moon, where there's no air. When gravity is the only thing around, all objects fall with the same acceleration, speed, and velocity, no matter what shape, size, or mass they have ... a feather and a bowling ball fall together. But when they have to fall through air, that's when heavy things fall faster.


In free fall the object with less air resistance falls with greater acceleration?

False


Why does a ball and marble fall at the same time?

A ball and a marble will fall at the same time because they are both affected by gravity equally, regardless of their size or weight. In a vacuum where air resistance is eliminated, all objects fall at the same rate regardless of their mass. This is explained by the principle of universal gravitation formulated by Isaac Newton.


Why is the accleration due to gravity same for all objects?

The acceleration due to gravity is the same for all objects because it is a constant value on Earth's surface. This value is approximately 9.81 m/s^2, regardless of the mass or size of the object. This uniform acceleration allows objects of different masses to fall at the same rate in a vacuum.