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.
The time it takes for a ball to fall is determined by gravity, which accelerates all objects at the same rate regardless of their mass or size. Therefore, the ball's diameter does not affect the time it takes to fall.
In a vacuum, both a ball and a piece of paper will fall at the same rate and hit the ground at the same time because they are subject to the same gravitational acceleration. However, in reality, the paper may experience more air resistance and fall more slowly than the ball.
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.
In a vacuum, they would hit the ground at the same time due to gravity. However, in the real world with air resistance, the bowling ball would typically hit the ground first because it has more mass and air resistance affects lighter objects more.
Their acceleration will be the same (9.8m/s^2) but they will not hit the ground at the same time because they are not the same mass. In addition, they will not hit the ground at the same time because they have different surface area which will affect air resistance.
Whichever you drop first will fall first and hit the ground first.If you drop them at exactly the same time from the sameplace, they fall together and hit the ground together.
Neither ... they would fall together.
The time it takes for a ball to fall is determined by gravity, which accelerates all objects at the same rate regardless of their mass or size. Therefore, the ball's diameter does not affect the time it takes to fall.
They would fall in same time in a vacuum, but if air is present the ball falls faster due to high air resistance on the leaf
They will fall at the same time, and also hit the ground at approximately the same time (given errors for air resistance).
In a vacuum, both a ball and a piece of paper will fall at the same rate and hit the ground at the same time because they are subject to the same gravitational acceleration. However, in reality, the paper may experience more air resistance and fall more slowly than the ball.
Discounting any friction with the air, they would both hit the ground at the same time.
If they're both dropped from the same place, on the same planet, then they'll both experience the same acceleration, and hit the ground with the same speed at the same time.
Both will fall at the same time in vacuum because there is no resistance.
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.
In a vacuum, they would hit the ground at the same time due to gravity. However, in the real world with air resistance, the bowling ball would typically hit the ground first because it has more mass and air resistance affects lighter objects more.
Both will reach the ground at the same time if they were dropped at the same time in a vacuum. This is a well proven fact that the mass has no effect on the acceleration of an object in a free fall in a vacuum.