Placeholder Image

Subtitles section Play video

  • ♪♪♪

  • Water is among the most abundant compounds in the universe.

  • It makes up about 70 percent of the Earth's surface and about 60 percent of our bodies.

  • And the odds are pretty good that you've already encountered a bunch of it today.

  • But despite how common water is, it continues to baffle scientists because it behaves unlike anything else out there.

  • Seriously, water is way weirder than you'd think.

  • First off, liquid water.

  • You know, the super familiar stuff you drink and wash your hands with.

  • Yeah, turns out, liquid water is complicated.

  • Because it seems to have not one, but two liquid phases that occur at the same time.

  • This likely happens at very low temperatures and high pressures

  • around -45 degrees Celsius and 2400 times the normal atmospheric pressure.

  • So, it's not something you'd encounter every day.

  • Regardless, under these conditions, water can spontaneously split into two liquid phases

  • that coexist like the oil and vinegar in your salad dressing: in separate layers, each with its own density.

  • The low-density portion is made of the standard tetrahedral pattern of water molecules, where a central molecule is linked to four neighbors.

  • But the high-density liquid has an extra molecule trying to squeeze into the group.

  • So far, scientists have only observed this in a computer model, partly because, well,

  • those temperature and pressure conditions are timely and expensive to replicate.

  • But if this idea holds up in physical experiments, it could help explain water's other weird properties.

  • Like how ice has regions of low and high density, which is how it floats on water.

  • These regions could somehow be frozen remnants of the two liquid phases.

  • And if so, the two densities could help us develop a model that predicts how water will

  • behave from super cold temperatures to the ones we experience all the time.

  • Since water is such an integral part of our world, a model like that could be useful for all sorts of research.

  • So, not too shabby!

  • Moving out of the liquid phase, we have our next weird thing: Scientists can't figure out when water starts to act like a glass.

  • If that sentence sounded weird... yeah, that's fair.

  • Because the glass phase is a weird one.

  • It's a sub-state between solid and liquid, where water can exist... well, like glass.

  • In short time scales, it looks like a solid, but in reality, it's very slowly relaxing into a liquid state.

  • Water isn't the only substance with a glass phase, but how it gets there seems to be unique.

  • Typically, as other substances are heated, they experience a gradual increase in heat capacity,

  • which is the amount of heat needed to raise their temperature one degree Celsius.

  • Their heat capacity continues to rise until it reaches the glass transition temperature,

  • where it suddenly jumps 100% higher.

  • At which point, it's officially in the glass phase.

  • But as water is heated, its heat capacity barely changes until all of a sudden it crystallizes and becomes a solid.

  • This has made it difficult for scientists to pin down a glass transition temperature.

  • Right now, they think it happens somewhere around -123 to -53 degrees Celsius.

  • But it's been so hard to figure out anything more specific that they've dubbed this windowno man's land.”

  • At this point, it's not totally clear what's going on, but at a minimum,

  • this tells us that something about water's heat capacity isn't normal.

  • That its temperature doesn't change like we'd expect.

  • Scientists have been looking into it, though, because understanding water's glass phase could really come in handy.

  • After all, this form of water is actually the most abundant in the universe and appears in a number of places, even in space aboard interstellar dust particles.

  • So, uncovering the secrets of glassy water could help us understand how it forms and shapes our solar system.

  • Of course, once you move past regular H2O, things start getting even weirder.

  • Like, apparently, you can't explain exactly how water acts in your body without involving quantum mechanics.

  • Scientists reported this in a 2019 paper, where they were studying mixtures of water and charged polymers.

  • These kinds of solutions are found in your joints, and they're really thick and viscous; much more than you'd expect.

  • Which is helpful for your knees, but overall, kind of confusing.

  • For a while, we thought this viscosity was caused by repulsive interactions between the polymers,

  • where similar electric charges repelled each other.

  • But in their paper, this team found there's much more to the story.

  • They discovered that the polymers' electric charge also affected how water molecules were interacting with each other.

  • These interactions made water's hydrogen bond network more ordered.

  • And that made it hard for molecules to move and hindered the flow of the solution, therefore making it more viscous!

  • That by itself was a cool result, because it showed you can't treat water as a neutral background for chemistry like we sometimes tend to do.

  • It's an active molecule you need to pay attention to.

  • But what's stranger is what this team found next.

  • In their study, they also looked at solutions of charged polymers and heavy water.

  • That's water made of oxygen and deuterium, a form of hydrogen with twice the usual mass.

  • This solution behaved a lot differently than the one with normal water.

  • The molecules interacted in different ways, and the viscosity was different.

  • In fact, these changes were so significant, they couldn't actually be explained with traditional chemistry models.

  • Instead, the team concluded you need to consider quantum mechanics to fully understand them.

  • It's hard to say exactly how the quantum world comes into play here.

  • But ultimately, the team suspects these effects influence how hydrogen bonds break in each type of water,

  • because that would affect the viscosity of the solutions.

  • So, water can't be ignored, and it's way more complicated than it seems on the surface.

  • But learning more about how this all works could help us learn more about applications

  • for polymers solutions and how water behaves in our bodies.

  • Because of its abundance and how big of a role it plays in our universe, we can take water for granted.

  • But it's really strange stuff.

  • And understanding why can help us advance lots of scientific fields.

  • So the next time you take a swig of water or see a raincloud, know that you're looking at something truly extraordinary.

  • Speaking of extraordinarylet me tell you about our patrons on Patreon.

  • We say it a lot around here, but we really can't thank our patrons enough.

  • Their support literally makes this show happen, and they're a community of smart, curious, wonderful people.

  • So if you're a patron, thank you!

  • And if you want to join our Patreon community and support free science education online, we'd love to have you.

  • You can learn more at Patreon.com/SciShow.

  • ♪♪♪

♪♪♪

Subtitles and vocabulary

Click the word to look it up Click the word to find further inforamtion about it