Wiki User
∙ 6y agoWant this question answered?
Be notified when an answer is posted
The balloon would have a greater acceleration because it has less mass compared to the volleyball. According to Newton's second law (F = ma), with the same force applied, an object with less mass will have a greater acceleration.
The acceleration of the swing would increase if one person pushed two people on it because the combined mass of the two people would be greater than just one person, requiring more force to achieve the same acceleration. Increased force would result in greater acceleration.
The shopping cart with greater mass will have lower acceleration compared to the shopping cart with lower mass. This is because acceleration is inversely proportional to mass when the force applied is kept constant.
it will grow hair
No.
They will be pushed closer together.
The object with the smallest mass would have the greatest acceleration when pushed with a force of 8.2 N, as acceleration is inversely proportional to mass when force is constant.
When you drop a balloon, gravity pulls it down towards the ground. As it falls, the air inside the balloon is pushed out through the opening, causing the balloon to deflate and eventually land on the ground.
Of course, it will not crack easily. After you pushed it up it, it will just go back to its normal shape.
A balloon powered car is moves because the balloon pushes out air. Whenever something exerts a force on something else (in other words, the balloon is exerting force on the air), then the object being pushed always exerts an equal and opposite reaction force on the object exerting force on it (in other words, the air exerts force on the balloon). Because the balloon is attached to the car, when the balloon is pushed by the air, the car is pushed. The law that for every force there is an equal and opposite reaction force is Newton's Third Law of Motion.
You can find the acceleration of a pushed object by dividing the net force acting on the object by its mass, using the formula a = F/m, where a is the acceleration, F is the net force, and m is the mass of the object.
Acceleration is 0.25m/s2 (A = force/mass).