> This comes down to how biology works in zero and partial g.
Why? Just spin the thing.
> Why? Just spin the thing
Sure. Let's put rats in centrifuges in space and see if they can reproduce successfully. Maybe there is a coriolis boundary. Maybe something weird happens.
If you make your centrifuge big enough, it's fine.
But yeah, sticking rats in a centrifuge is probably a better first step than starting with humans.
> If you make your centrifuge big enough, it's fine
We don't know this! We don't know how (or even if) an embryo develops under the Coriolis force, or with a gravity gradient.
If you make it big enough, there's no discernible gradient and not much of a Coriolis force.
> Why? Just spin the thing
Sure. Let's put rats in centrifuges in space and see if they can reproduce successfully. Maybe there is a coriolis boundary. Maybe something weird happens.
If you make your centrifuge big enough, it's fine.
But yeah, sticking rats in a centrifuge is probably a better first step than starting with humans.
> If you make your centrifuge big enough, it's fine
We don't know this! We don't know how (or even if) an embryo develops under the Coriolis force, or with a gravity gradient.
If you make it big enough, there's no discernible gradient and not much of a Coriolis force.