What kind of object in what kind of motion? The question is too vague to answer, and the forces depend on the properties of the object and its environment anyway. For example, there might ... or might not ... be significant electromagnetic and/or gravitational forces acting on the object (technically, any real object in the real universe WILL have electromagnetic and gravitational forces acting on it, but they may be insignificant in some cases).
Some forces that can act upon a moving object include friction, air resistance, gravity, and applied forces like pushing or pulling. These forces can affect the speed, direction, and motion of the object.
Some forces that affect an object's motion include gravity, friction, air resistance, and applied forces like pushes or pulls. These forces can either speed up, slow down, or change the direction of an object's motion.
No, of course not! We ourselves we change our motion!
The motion of an object is determined by its velocity, acceleration, and the forces acting upon it. Newton's laws of motion describe how these factors interact to determine the motion of an object.
The motion of an object is determined by the forces acting upon it. These forces may include gravity, friction, air resistance, and applied forces. The interaction of these forces decides the object's speed, velocity, and direction of movement.
Some forces that can act upon a moving object include friction, air resistance, gravity, and applied forces like pushing or pulling. These forces can affect the speed, direction, and motion of the object.
Some forces that affect an object's motion include gravity, friction, air resistance, and applied forces like pushes or pulls. These forces can either speed up, slow down, or change the direction of an object's motion.
No, of course not! We ourselves we change our motion!
The motion of an object is determined by its velocity, acceleration, and the forces acting upon it. Newton's laws of motion describe how these factors interact to determine the motion of an object.
The motion of an object is determined by the forces acting upon it. These forces may include gravity, friction, air resistance, and applied forces. The interaction of these forces decides the object's speed, velocity, and direction of movement.
Yes, it is possible for an object to not be in motion and still have forces acting on it. This situation could occur if the forces acting on the object are balanced, resulting in a state of equilibrium where there is no net force causing motion.
-- First of all, motion doesn't require any force.-- If the forces on an object are unbalanced, then the object's motion changes. Always.-- If the forces on an object are balanced, then the object's motion doesn't change.
That depends. If no forces act on the object, it will. If forces do act on the objects, such forces may change the object's velocity.
Newton's first law states that an object at rest will stay at rest, and an object in motion will stay in motion unless acted upon by an external force. This means that an object's inertia, or resistance to changes in motion, is related to the forces acting upon it. Newton's third law states that for every action, there is an equal and opposite reaction. This means that the forces acting on an object are balanced, which affects its inertia and overall motion.
Assuming this is a vacuum: Motion would occur only if there is no secondly force acting on the object with the same magnitude(strength) but has the opposite direction to the force you're acting upon this object.
An object can be in motion due to the presence of forces acting upon it. These forces can include pushing or pulling forces, such as friction, gravity, or an external force applied to the object. Once a force is applied to an object, it can cause the object to accelerate and move in the direction of the force.
An object will continue in its state of motion unless acted upon by an external force, as described by Newton's first law of motion. This means that if no external forces are applied, the object will either remain at rest or continue moving at a constant velocity.