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If there is no counter-force (usually friction), the object will accelerate.
the object will move
While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".
Yes the action applies to the object that the force is exerted on while the reaction applies to the object applying the force.
F = ma, or rearranged, a = F / m. So while an object with twice the mass feels twice the force due to gravity, that turns out to be precisely the amount of force required to keep the acceleration constant when the mass is doubled.
There's far too little information in the question to formulate any reasonable answer. The question could cover a myriad of sundry different situations. For example: -- If you double the force you're applying to a brick wall, nothing happens to any distance you might be interested in. -- If you double the force you apply to a bowling ball in space, then its acceleration doubles, and the distance it travels in any reference time period quadruples. -- If you double the force you're applying backwards to the front bumper of a car that's coasting forward, then its acceleration also doubles, but the distance it travels in any reference time period decreases by 75%, at least until it stops. -- If you double the tangential force applied to an object that's in orbit around the sun, then depending on what portion of its orbit it happens to be in at the moment, either the major or minor axis of its orbit begins to grow faster, and the distance it travels during each orbital period increases in a way that can't be predicted without a lot more information.
Friction. Friction is usually when some force is rubbing against the object. An example is how when you activate the breaks of a car that it would stop because their is this device that goes against the tire to cause it to stop. The heat from the friction generally slows down the object while also applying force to the object.
If there is no counter-force (usually friction), the object will accelerate.
It depends on the amount of force force=distance*acceleration
the object will move
While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".
Yes the action applies to the object that the force is exerted on while the reaction applies to the object applying the force.
F = ma, or rearranged, a = F / m. So while an object with twice the mass feels twice the force due to gravity, that turns out to be precisely the amount of force required to keep the acceleration constant when the mass is doubled.
F=m.a , a=F/m; acceleration is directly proportional with force. acceleration increase while force increase.
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According to Law of Inertia, an object will remain in its state of motion, either at rest or moving until an external unbalanced force acts on it. So if the object is at rest, some external force (F) has to be applied in order to move that object. Law of Inertia is actually a second law, out of three Newton's laws of motion.
It Will increase