magnetic force
A pushing force is applied in the direction of an object's motion, causing it to move away from the force. On the other hand, a pulling force is applied in the direction opposite to an object's motion, drawing it towards the force. In essence, pushing moves an object away, while pulling brings it closer.
Yes, a force can make an object slow down by applying a force in the opposite direction to the object's motion. This force works to counteract the object's velocity and eventually brings it to a stop.
To draw or pull something to itself means to exert a force that brings another object closer towards it. This action typically involves a physical or magnetic attraction that causes the objects to come into closer proximity.
The force that stops an object from moving is typically friction. Friction occurs when two surfaces rub against each other, creating a force that opposes the motion of the object. This force eventually brings the object to a stop.
A single force on an object, or a net force ... the sum of all forces on it when the sumis not zero ... always changes the object's velocity ... speed, or direction, or both.
False. A lever to multiply the force exerted has its fulcrum closer to the object than to the force is applied. This will increase the force but decrease the distance the object moves compared to the force end.
When an object gets closer to another object, the gravitational force between them increases. This is because the gravitational force is directly proportional to the product of the masses of the objects and inversely proportional to the square of the distance between them, as described by Newton's law of universal gravitation.
The strength of a magnet's force increases as the magnet gets larger or closer to an object.
The force that occurs when molecules of an object are pushed together is called compression force. This force causes the molecules to move closer to each other, resulting in a decrease in the object's volume.
the buoyant force points up and gravity goes down that's why we are balanced.
Yes, if the fulcrum is closer to the effort, the force required to lift an object will be less because the lever arm is shorter. This creates a mechanical advantage in which less force is needed to move the object.
do you exert more force when you are further from the fulcrum