Explain how bumper cars are an example of Newton's Third Law of Motion.(1 point)%0D%0AResponses%0D%0A%0D%0AWhen bumper cars collide, they will both move in the same direction.%0D%0AWhen bumper cars collide, they will both move in the same direction.%0D%0A%0D%0AWhen bumper cars collide, they will bounce apart with increased force.%0D%0AWhen bumper cars collide, they will bounce apart with increased force.%0D%0A%0D%0AWhen bumper cars collide, they will bounce apart with equal force.%0D%0AWhen bumper cars collide, they will bounce apart with equal force.%0D%0A%0D%0AWhen bumper cars collide, one car will transfer its force to the other, and then they will bounce apart.
The correct response is: When bumper cars collide, they will both move in the opposite direction.
When bumper cars collide, they demonstrate Newton's Third Law of Motion, which states that for every action, there is an equal and opposite reaction. This law can be observed in the following way:
- When bumper cars collide, they will bounce apart with equal force. This means that the force exerted by one bumper car on the other is the same as the force exerted by the second bumper car on the first one. The force is equal and opposite, ensuring that the total momentum of the system remains constant. As a result, the cars move away from each other.
- Another way to describe this is that when the bumper cars collide, one car will transfer its force to the other, and then they will bounce apart. The force exerted by each car on the other causes a transfer of momentum. This transfer of momentum ensures that both cars experience a change in velocity and move in opposite directions.
In summary, bumper cars exemplify Newton's Third Law of Motion by demonstrating that when they collide, they exert equal and opposite forces on each other, leading to a transfer of momentum and causing them to move apart in opposite directions.
When bumper cars collide, they demonstrate Newton's Third Law of Motion, which states that for every action, there is an equal and opposite reaction. In this case, the action is the force of one bumper car hitting another, and the reaction is the force exerted back onto the first car.
To understand this concept, imagine two bumper cars driving towards each other. As they collide, the force of one car hitting the other is transferred. According to Newton's Third Law, the second car exerts an equal and opposite force back onto the first car.
This means that both cars experience the same amount of force but in opposite directions. As a result, they will both move in the same direction, bounce apart, and continue in opposite directions.
So, when bumper cars collide, they will bounce apart with equal force, in line with Newton's Third Law of Motion.