The surface of an object affects the aerodynamic drag: a force which acts against the direction of motion.
Yes it does.
Circular motion would change the direction of an object but would not affect the object's speed.
Friction or gravity .
Newton's second law of motion covers this.The net force on an object accelerates the object.
If there is zero net force on an object, the object will not accelerate. (It's velocity will not change.)
The relationship between the coefficient of kinetic friction ( denoted as uk ) and the mass, surface area, type of material or the speed of the object, is that the uk between a moving object and a non-moving object affects and distributes it on every points of an atom or molecule in all regions of both of the surface area of the two objects in contact with the object in motion, also the material from the object in motion relatively in contact to the surface of the other object which is not moving at all, determines the speed of the object, whether the material is rough that has lesser speed than that of a smooth surface or smooth vice versa.
The surface of an object affects the aerodynamic drag: a force which acts against the direction of motion.
the object has less mass. the object has a large surface.
the object of motion is akantutan
Accelerates the motion of an object.
Yes. Think of a glider, and then imagine folding its wings in half.
When the object tumbles irregularly, rather than presenting its most aerodynamic surface to oncoming air.
If the surface is sticky the energy needed to break the "sticky" ionic bonds will not be able to contribute to the motion of the object rolling down the inclined surface.
Balanced forces do not change its motion (no acceleration). Unbalanced forces changes the motion of the object (acceleration).
This will cause the object to slow down.
It depends on the surface on which the object is moving, and also any other forces - such as gravity.
Friction always resist motion if the object is sliding on surface.
Acceleration ... whether or not it was in motion initially.