Imagine you slapping your friend back, imagine that mark that looks like a hand. That is the energy your hand made. Now imagine a small insect on that mark. That is how little of that energy that insect can get of your handslap.

Imagine you slapping your friend back, imagine that mark that looks like a hand. That is the energy your hand made. Now imagine a small insect on that mark. That is how little of that energy that insect can get of your handslap.

Imagine you slapping your friend back, imagine that mark that looks like a hand. That is the energy your hand made. Now imagine a small insect on that mark. That is how little of that energy that insect can get of your handslap.

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There’s a few reasons, others here are mostly focusing on how the fly survives a big force. I’ll focus on why the force isn’t that big to begin with.

You’re not transferring that much momentum to the insect if you think about it (or calculate it).

If you slap a bowling ball, your hand slows down by a lot, i.e. you transferres much momentum to the bowling ball. But a fly doesn’t really slow down your hand at all.

Momentum is mass times velocity. Force is mass times acceleration, i.e. how long it takes the fly to reach it’s end velocity. Your hand can deform, and the air acts as a cushion aswell. If you imagine falling onto a brick wall that hurts way more than falling onto a soft matress. You have more time to slow down gently on the matress. So even though your whole momentum gets down to zero, it takes a longer time so the maximum force is smaller (but acts on you for longer)

Will try to answer as easy as possible.

To change the direction of an object depends on one thing: it’s weight (which it’s mass times acceleration), because depending the weight of it is directly proportional to the force required to change it’s direction and that object has resistance to that change. If the weight is little being directly proportional then the force on that object is small.

So even though your slap might have a big force, because the object(being) you are hitting is small only a small part of that force is transferred before it has the same direction as your slap and so the impact is smaller.

The amount of force is distributed across the area of your hand. If the insect is small enough, there’s not a lot of force being applied to the area they occupy.

It’s the same idea that makes sharp objects able to cut things. You’re only applying a low amount of force but it’s focused into a tiny point, so it will rip through things very easily.

Bugs & insects also have an exoskeleton instead of a normal skeleton. So the force you apply is acting on the most rigid structure. If you hit a fleshy animal, you might not break a bone but you can cause other damage. If you hit a bug, you’ve gotta break that exoskeleton for it to really do anything. A small amount of force that is focused into its small area will probably do the job but if you’re wasting energy hitting a large surface area you will need a lot more force.

There’s a few reasons, others here are mostly focusing on how the fly survives a big force. I’ll focus on why the force isn’t that big to begin with.

You’re not transferring that much momentum to the insect if you think about it (or calculate it).

If you slap a bowling ball, your hand slows down by a lot, i.e. you transferres much momentum to the bowling ball. But a fly doesn’t really slow down your hand at all.

Momentum is mass times velocity. Force is mass times acceleration, i.e. how long it takes the fly to reach it’s end velocity. Your hand can deform, and the air acts as a cushion aswell. If you imagine falling onto a brick wall that hurts way more than falling onto a soft matress. You have more time to slow down gently on the matress. So even though your whole momentum gets down to zero, it takes a longer time so the maximum force is smaller (but acts on you for longer)