The object is accelerated in the direction of the net (or resultant) force.
If a force is being applied to a moving object, it will change its velocity (it will accelerate) appropriately.
When a balanced force is applied to an object, the object will remain at rest or continue moving at a constant velocity. This is because the net force on the object is zero, resulting in no change in its motion.
When an unbalanced force is applied to a moving object, the object will experience acceleration in the direction of the force. If the force is in the same direction as the object's motion, it will speed up. If the force is in the opposite direction, it will slow down or change direction.
When balanced forces are applied to a moving object, the object likely slow and eventually stop. How quickly that occurs depends on the amount of force.
The friction produced that stops an object moving when force is applied is 'static friction'.
Static friction. The frictional force is greater then the force applied, meaning the object can't move.
Static friction is the friction that prevents an object from moving when a force is applied. It occurs between stationary surfaces and must be overcome by an applied force in order for the object to start moving.
Yes, static friction is the force that prevents an object from moving when a force is applied to it. It arises when the applied force is not strong enough to overcome the frictional force between the object and the surface it is resting on.
The object will not move!!!
Static friction is the friction that prevents an object from moving when a force is applied. It acts in the opposite direction of the applied force and increases until the force surpasses the maximum static friction force, allowing the object to move.
The friction of a non-moving object is called static friction. It is the force that prevents the object from moving when a force is applied to it.
An object keeps moving once an applied force causes it to start moving because of inertia, which is the tendency of an object to resist changes in its motion.