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For a body at rest, that's impossible. The only way that could happen is if you didn't take all the forces into account. You must have neglected friction (including air friction) or there is an error in the measurements.Actually the answer to that question is pretty simple. Its because action and reaction are not on the same body, for eg: when a u kick a football the action is on the football which travels away, while the reaction is on your leg which hurts.ANSWER2Newton's Laws of motion involve Equilibrium,Conservation of Energy. The forces do not balance when there is not Equilibrium.
Yes, there is! Whatever you do, something will always happen depending on what you did. For example; if you did something as simple as helping someone across the street, the reaction may be that person feels that little bit better about life, and they then may do something nice to someone else (or even in return to you)!Even more simpler things like brushing your teeth twice a day every day has a reaction - you will have clean and healthy teeth and a nice smelling mouth! (which is better than a foul smelling mouth, don't you think?)===================For every action there is an equal but opposite reaction. That is Newton's Third Law.
There are several forces involved while riding a skateboard. The force of friction (air resistance and contact with ground) acting against the motion and the pushing force from when you push off with your foot acting with motion. There are also several normal reaction forces, the weight of the person on the skateboard and the weight of the skateboard on the ground.
Both forces can be called "weight".The gravitational force that attracts a person's body toward earth is calledthe person's weight on the earth.The gravitational force that attracts the earth toward a person's body could becalled the earth's weight on the person's body.The forces are both there, and they're equal.
Some do and some don't. In the case of someone sitting on a chair, they exert a downward force on the chair due to their weight. The chair exerts an equal and opposite reaction force on them but, since this upward force acting on the person is equal to their weight, the net force is zero and the person does not accelerate. However, consider now if the person pushed themselves up off the chair with their hands. They are now exerting an additional force on the chair with their arms along with the force due to their weight. The chair will exert a reaction force on the person that is equal and opposite to the combined downward force due to the person's weight and their arms pushing. Since it is equal to the weight plus the pushing force of the arms, it will be greater than the downward force on the person due to their weight and a net upward force will be produced, accelerating the person upwards.
The action and reaction forces act on different objects. For two forces to cancel each other - and provide a net force of zero, for Newton's First Law - they must act on the same object.
It does work. The force of a person hitting a ball "cancels" out the force of the ball moving and brings it to a stop (to zero). Only then does the ball move in the direction it is hit, due to the overwhelming force applied by the person.
When a person is sitting still in a chair, the action and reaction forces meet along his bottom. The 'action' is directed downward and is the person's weight, the result of the gravitational attraction between the Earth's mass and the person's mass. The 'reaction' is directed upward, and is the force developed in the structural materials of the floor and the chair. Since the action and reaction forces are equal and opposite, the net force on the person's bottom is zero, and he does not accelerate vertically.
Because the ball 'flexes' - thus losing a tiny percentage of its energy.
It does work. The force of a person hitting a ball "cancels" out the force of the ball moving and brings it to a stop (to zero). Only then does the ball move in the direction it is hit, due to the overwhelming force applied by the person.
It does work. The force of a person hitting a ball "cancels" out the force of the ball moving and brings it to a stop (to zero). Only then does the ball move in the direction it is hit, due to the overwhelming force applied by the person.
BECAUSE THE FORCES AREN'T EQUAL IF THEY WERE THE BALL WOULD FALL STRAIT DOWN. the bat (even if it were lighter than the ball) has more inertia/energy which cancels out the kinetic energy of the ball, the residual kinectic energy of the bat that isn't canceled out changes the direction of the ball, the more direct the angle the more effective and further the ball will go
Action: Force from muscles used to push against the floor.Reaction: Floor pushes body up.
They are equal and opposite (Newton's third law).Each action has an equal an opposite reaction. For example: pulling on a rubber band and letting it go will cause it to fly around. This is the action and related response or reaction desired.
The two forces ("action" and "reaction") act on different objects (you push against the Earth, the Earth pushes against you), so there is no guarantee that forces on one specific object (you, who do the walking) are always balanced.
For a body at rest, that's impossible. The only way that could happen is if you didn't take all the forces into account. You must have neglected friction (including air friction) or there is an error in the measurements.Actually the answer to that question is pretty simple. Its because action and reaction are not on the same body, for eg: when a u kick a football the action is on the football which travels away, while the reaction is on your leg which hurts.ANSWER2Newton's Laws of motion involve Equilibrium,Conservation of Energy. The forces do not balance when there is not Equilibrium.
because there is a third and separate action.