What if there was no space in atoms?

If there were no empty space the atom would probably not exist as there wouldn’t be any force keeping the electron-proton interaction in check resulting in zero distance between them, resulting in an infinite force of attraction between them, resulting, probably, in the electron and proton crashing into each other …

Can humans fit in sugar cubes?

Almost all of ordinary matter (99.9999999\% of it) is empty space. If you took out all of the space in our atoms, the entire human race (all 7 billion of us) would fit into the volume of a sugar cube.

How much empty space is in the human body?

Originally Answered: What percentage of your body is empty space? So, the average 70kg human constitutes 7*10^27 atoms, and atoms are very vastly made up of empty space, and therefore the human body is roughly 99.9999999\% empty space.

Is the inside of an atom void?

What was thought to be void inside an atom is NOT void. It is not even 0,9999999999\% empty, it’s full of quantum foams, etc. But between you and an object, it’s full 999999999999\% empty. So yes, it’s full foams,etc inside an atom, and 999999999\% VOID (which is outside it)

What would happen if there was no atoms in the universe?

Atoms in the Lucretian universe are accompanied by void – completely empty space, without any particles in it – both outside and within objects. Without it, there would be no motion, because there would be no space without particles in it into which particles could move, and a ball of wool would weigh the same as a ball of lead.

How empty is the empty space inside an atom?

Empty space inside an atom is not empty. What was thought to be void inside an atom is NOT void. It is not even 0,9999999999\% empty, it’s full of quantum foams, etc. But between you and an object, it’s full 999999999999\% empty.

What happens when atoms get too close to each other?

As atoms get too close to one another their charges begin to repel each other. Once they’re close enough that they can “see” the other atom, the electrons on the near side of both atoms begin to repel each other and move more to the far side of both atoms. This leaves the positively charged nuclei facing each other.