The answer your teacher want's: Effort to move the load inceases, distance the load moves in relation to the force end increases.
In real life you Little sister sits on the low end of the tetertotter and giggles because you arent heavy enough to lift her up.
The distance is longer than the lift or the drop, but the force you need is less than the weight of the load.
Work
Force of gravity, Fg, is directly proportional to the product of the masses of the two interacting objects and inversely proportional to the square of the distance between them. Fg = Gm1m2/r2 Therefore, when either of the masses increase, Fg increases proportionally.
Primary is the main thing that happens. The side effect is what happens because of the Primary thing.
Since seconds measure time, and a meter is a measure of distance, one could say that a given distance one meter long will last an infinite number of minutes. However, what happens in that meter during eternity will likely involve a whole lot of change!
The torque will be reduced. The torque is found by the cross product of the distance from the fulcrum and the applied force. Assuming the force is applied perpendicular to the lever, you merely multiply the two. So if the force applied remains constant and you shorten the distance to the fulcrum, you are reducing one of the values while the other remains constant. When multiplied, this will reduce the total. Therefore the torque will be reduced. In effect, the lever will have a weaker action.
The closer the load is to the fulcrum the greater the mechanical advantage. The closer to the fulcrum, the less the load moves when the lever is used.
Nothing happens. Distance between crests is a measure of frequency; amplitude is a measure of the strength, the height of the wave, or auditory volume of the signal.
During flexion, the distance between the spinous processes is increased.
the difference is the position of the fulcrum. a first class lever has the fulcrum between the lode and applied force. a second class lever has the load between the fulcrum and applied force. A third class lever has the applied force between load and fulcrum. The load happens to be the thing that you are affecting in the system. On a seesaw the load and applied force changes as either kid goes up, but the lower kid is always the force and upper is the load with the fulcrum in the middle. this happens to be a first class lever. a second class lever could be a bottle cap opener with the fulcrum at the end the bottle cap(load) in the middle and you pushing (force) on the other. a third class lever are like tweezers with the fulcrum on the closed end, force is you pushing in the middle, and affected load is whatever you pick up. There are also compound levers like nailclippers, but by diagramming the whole system it should be pretty easy to discover that it is a first class lever. It's compund because of the use of a lever system
Nothing.
the gravitational force between them decreases.
the force of attraction get weaker the more the distance grows between magnetic fields
When the distance between the centers of two objects is doubled, the gravitational forces between the objects are reduced by 75% .
The size of the force decreases. It is inversely proportional to the square of the distance.
the stronger the electric force
It increases.