For fun: read the parent as implying that wedrifid has slept on top of a cubic meter of lead for decades.
It’s so soft! There is no other metal that I’ve slept on for decades that is more comfortable than lead.
I haven’t tried a water bed filled with mercury yet. That actually has potential. The extra mass would absorb the impact or rapid movement of a human more smoothly while maintaining malleable fluidity over a slightly longer timescale. Plus if you attach a glass tube near the head of the bed you can calculate your weight based off changes in mmHg!
It’s not the mass, it’s the viscosity. The higher density would result in a ‘firmer’ feel, since less immersion would be needed for the same amount of buoyant force.
A more reasonable option might be Gallium-which would be firm on initial contact, but then liquefy.
No, really, it’s both. I edited out out viscosity since either would be sufficient and I happened to be certain about mass but merely confident about viscosity.
I assume that the primary mechanism by which mass absorbs impact would be inertia.
Malleable is a property that liquids don’t have, so what did you mean by ‘maintaining malleable fluidity’ that doesn’t also result from having the liquid in a closed container with some airspace and some elasticity? How would more inertia help absorb impact (spread the impulse out over a longer period of time)?
It’s so soft! There is no other metal that I’ve slept on for decades that is more comfortable than lead.
I haven’t tried a water bed filled with mercury yet. That actually has potential. The extra mass would absorb the impact or rapid movement of a human more smoothly while maintaining malleable fluidity over a slightly longer timescale. Plus if you attach a glass tube near the head of the bed you can calculate your weight based off changes in mmHg!
I used to think that my mercury bed was a bad idea and mad as a hatter. But then I gave it a fair try for a few months, and boy did my mind change!
It’s not the mass, it’s the viscosity. The higher density would result in a ‘firmer’ feel, since less immersion would be needed for the same amount of buoyant force.
A more reasonable option might be Gallium-which would be firm on initial contact, but then liquefy.
No, really, it’s both. I edited out out viscosity since either would be sufficient and I happened to be certain about mass but merely confident about viscosity.
I assume that the primary mechanism by which mass absorbs impact would be inertia.
Malleable is a property that liquids don’t have, so what did you mean by ‘maintaining malleable fluidity’ that doesn’t also result from having the liquid in a closed container with some airspace and some elasticity? How would more inertia help absorb impact (spread the impulse out over a longer period of time)?
That’s actually a neat idea. You could use gallium/indium/tin alloy perhaps. Would be easily the most expensive fluid bed.