RobusEtCeleritas t1_ivrcc8y wrote
It's not because they necessarily "interact more readily", it's just that the kinematics is more favorable when they do interact.
If you want to slow something down, you want to take as much kinetic energy away from it as possible with each collision, and simple kinematics shows that the optimal way to do that is for the neutron to collide with a nucleus of roughly the same mass, so ideally a proton.
That's why hydrogen, and hydrogen-containing compounds are very good neutron moderators. The lighter the nucleus the better.
2science t1_ivrmfug wrote
Would that mean that the liquid hydrogen is even better?
mfb- t1_ivrn8vv wrote
Liquid hydrogen is awkward to work with and water has a higher density of hydrogen atoms.
2science t1_ivrp6fv wrote
How is that water has higher density of hydrogen if it contains also oxygen in it?
ScootysDad t1_ivsvi4c wrote
Surprisingly, water is 14x denser than liquid hydrogen. The bonding angle of the H-O-H makes the O slightly positive and the H slightly negative which then tends to attract another H from the other H-O-H and holds it closer (surface tension). Even at cryogenic level water will have more H than liquid H.
2science t1_ivsvpp7 wrote
I wonder whether water is considered denser than liquid hydrogen because it's heavier.
ccdy t1_ivtgbbo wrote
Water has a hydrogen atom number density of 111 mol/L, while that of liquid hydrogen is 70.3 mol/L. No, it's not just due to water having a higher molecular weight.
[deleted] t1_ivtwau5 wrote
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Calixare t1_ivtxzzh wrote
So, BeH2 and liquid NH3 will be slightly better. Of course, applying water is much easier.
ScootysDad t1_ivvp1bu wrote
The BeH2 molecule has a very linear structure with the H atoms bonded "inline" so they cannot be as densely packed as H2O. Further, it's actually a solid and form a kind of crystalline (lots of open space). NH3 (amonia) bonding is something vague for me but I think it has something to do with the electron orbital in O that give is a higher charge than N thus allowing it to be more attractive than N in that configuration. I don't think it comes even close.
Calixare t1_ivwo620 wrote
But they do. Respectively, 118 and 120 mol H per L.
[deleted] t1_ivsx0wr wrote
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thewiselumpofcoal t1_ivswjye wrote
Liquid hydrogen has a density of 71 kg/m^3, water is at roughly a thousand, so it's 14 times denser. They both have 2 hydrogen atoms per molecule and water molecules are 9 times more heavy than H2, so in water there's just more molecules per unit of volume.
Between water molecules there's a much stronger attractive force than between hydrogen molecules, so they are pulled much closer together. So much that liquid water is famously even denser than ice.
[deleted] t1_ivrpf3p wrote
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[deleted] t1_ivs5xl4 wrote
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hifructosetrashjuice t1_ivtekb4 wrote
liquid hydrogen or liquid methane is great moderator when you need very cold neutrons. remember you can cool down neutrons only down to energy of thermal motion - liquid hydrogen is pretty cold at 20K
Yaver_Mbizi t1_ivuk2vl wrote
And if you want ultracold neutrons, superfluid isotopically-pure Helium-4 is by far the best, with deuterium ice in second place.
mfb- t1_ivx1xin wrote
> isotopically-pure Helium-4
Does that need any special purification effort? Helium-3 is already a tiny fraction of the helium we extract.
chugalug_donna t1_iw19dy4 wrote
You can distill them apart, it's part of how dilution refrigerators work
mfb- t1_iw19xaz wrote
I know it's possible, but I'm asking if it's necessary for this application.
Yaver_Mbizi t1_iwcnub0 wrote
Sorry for taking so long to reply - I first wanted to get the numbers right and then kinda forgot about this comment.
> Does that need any special purification effort?
Yes. Specifically something called "superleak" or "superfluid helium filter" is used. It's basically a filter with material so tightly compressed that only a superfluid can go between the particles. As helium-3 reaches superfluidity at a much lower temperature level than helium-4, the isotopes can be thusly separated.
>Helium-3 is already a tiny fraction of the helium we extract.
Yep, but the less of it, the better. The natural content is about 10^(-6), whereas by using a superleak you can get something around 10^(-11), which is much better.
hifructosetrashjuice t1_ivtf9aw wrote
also you need to keep your material chemically simple, because when interacting with neutron proton is kicked out of molecule. this leaves water, because all products of that can react back forming water again, same goes for hydrogen. this does not work for oil, for example, that is if you wanted to put oil in nuclear reactor for some reason
luckyluke193 t1_ivshs0u wrote
You generally don't want to fill a nuclear reactor with a highly explosive liquid.
mikmckn t1_ivu92ao wrote
As long as you don't allow any oxygen in, hydrogen is pretty tame. That's one of the safety issues with compromised water cooled reactors; the heat causes the water to split into it's component atoms and you end up with pure hydrogen, pure oxygen and a whole lot of heat.
That's why it's important to keep water on your core.
[deleted] t1_ivsiuod wrote
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