it would be 9.8 meter per second. anything that isn't subject to air resistance(like paper) will fall at this rate for this is the acceleration of gravity,
on the moon, which object would fall with the same acceleration
In a vacuum chamber. C. On the moon.
In a vacuum chamber. C. On the moon.
all three.
they would each hit at precisly the same time because there is no gravity on the moon, therefore, nothing would bring down the objects according to weight.
Yes
they would not differ
on the moon, which object would fall with the same acceleration
Assuming both were dropped from the same height above ground, in a vacuum both would hit the ground at the same time. In a significant atmosphere (e.g. average ground-level on Earch) the bowling ball would hit the ground first.
In a vacuum chamber. C. On the moon.
In a vacuum chamber. C. On the moon.
In a vacuum chamber. C. On the moon.
No. They will hit the ground at the same time. The inertia for the heavier ball will be greater, but the acceleration for both will be the same, and both would (if the air resistance is the same for both) hit at the same time.
all three.
they would each hit at precisly the same time because there is no gravity on the moon, therefore, nothing would bring down the objects according to weight.
i dont knoe
The Weight of an object is not a function of Height. When an object is dropped from a height, it accelerates up to a fixed velocity. It strikes the ground that results in a Force of the imact. The force required to Stop an Object is proportional to its Mass and the acceleration(or deceleration which is the change in velocity over time). Force = 1/2 Mass X Acceleration The Acceleration(or deceleration) is an instantenous stop so it would be approximated by 1/2 the speed it had before it hit the ground. Use that equation with the correct units and you can calculate the Force. I hope this is the answer to your Q.