because the force the drives it
Any amount of force, no matter how large or small, will increase or decrease the speed of any mass, no matter how large or small. But if you specify how much you want the object's speed changed and how quickly you want it done, then you have specified the acceleration you want. In that case, the larger the mass is, the more force it will take to accomplish that assignment.
The large mass can have proportionately more force applied to it than to the smaller mass.
Gravitationally, the same force does not affect a small mass and a large mass.The small mass is acted upon by a smaller gravitational force, and the large massis acted upon by a larger gravitational force. The result is that the small mass andthe large mass fall with the same acceleration, and meet the ground with the samespeed. During the fall, onlookers typically nudge each other and remark to each other:"My word! The large mass weighs more than the small mass!" They are correct in theirimpression, and the scientific reason behind their perspicacious observation is the factthat the gravitational force acting on the large mass is greater than the gravitationalforce acting on the small mass.
Yes. All masses large and small, at the same location, exhibit the same acceleration of gravity.
Force = mass x acceleration, therefore, acceleration = force / mass.Force = mass x acceleration, therefore, acceleration = force / mass.Force = mass x acceleration, therefore, acceleration = force / mass.Force = mass x acceleration, therefore, acceleration = force / mass.
These three variables are related by Newton's Second law: Force = mass x acceleration.
Strictly speaking its not the same . This equation calculates the acceleration: acceleration = ( G * ( m1 + m2 ) ) / d2 where: G = newtons gravity constant m1 = earths mass (kg) m2 = objects mass (kg) d = distance between centres of gravity (metres) The earths mass is so large however, only a significantly large object mass would make a real difference to the acceleration.
Any unbalanced force will make any mass accelerate. Clearly, a small force on a big mass will result in a small acceleration, as F=ma The previous answer on gravitation was not very helpful
Momentum is the concept that links the action of a force and the change of speed it produces. It accounts for the fact that a force will produce a large acceleration in a small mass but a small acceleration in a large mass. If this law was not universal, then the outcomes of identical interactions would vary, contrary to the basic tenets of physics.
Momentum is the concept that links the action of a force and the change of speed it produces. It accounts for the fact that a force will produce a large acceleration in a small mass but a small acceleration in a large mass. If this law was not universal, then the outcomes of identical interactions would vary, contrary to the basic tenets of physics.
Gravitationally, the same force does not affect a small mass and a large mass.The small mass is acted upon by a smaller gravitational force, and the large massis acted upon by a larger gravitational force. The result is that the small mass andthe large mass fall with the same acceleration, and meet the ground with the samespeed. During the fall, onlookers typically nudge each other and remark to each other:"My word! The large mass weighs more than the small mass!" They are correct in theirimpression, and the scientific reason behind their perspicacious observation is the factthat the gravitational force acting on the large mass is greater than the gravitationalforce acting on the small mass.
Force = mass x acceleration; acceleration = force / mass. If force is zero, then obviously, acceleration will also be zero.