ANY net force will cause an acceleration. If the force is reduced, there will be less acceleration, though.
If everything else stays the same then acceleration will be proportional to the force.
If force increases while mass stays the same, acceleration will also increase. This is because acceleration is directly proportional to the force applied, according to Newton's second law of motion (F=ma). So, as the force increases, the acceleration of the object will also increase if the mass remains constant.
Increasing the distance will not affect the time the velocity stays the same. Time the velocity stays the same depends on the acceleration.
When mass increases, velocity remains constant if the force applied remains constant. However, if the applied force stays the same, an increase in mass will require more force to achieve the same acceleration, which may lead to a decrease in velocity.
the acceleration of the object.
no net force on it and it keeps travellind with constant velocity or stays without moving.
The equation for force is F = M x A F = Force, M = Mass, A = Acceleration Based on the equation, in order for force to increase, and mass stay the same, you will have to increase the accelaration of the object in motion.
If the force applied to a mass increases, its acceleration will also increase, assuming the mass stays constant. This is described by Newton's Second Law, (F = ma), where force is directly proportional to acceleration when mass is constant. Conversely, if the force decreases, the acceleration will also decrease as per the relationship defined by the law.
Assuming that mass stays constant, a decrease in force will result in a corresponding decrease in the acceleration of the object being acted upon by the force.
The acceleration will be cut in half. This is because, according to Newton's second law (F = ma), if force remains constant while mass doubles, the acceleration will be halved.
It increases. (Standard rocket science.)
It increases. (Standard rocket science.)