Mercury Shouldn't Be Liquid. But It Is.

Yeah I’d imagine it didn’t work out well for him

ba dum tsss

literally

Dead wong

Or depending on his believes he may enter into the eternal life realm… 😂 so he could be right!

I was thinking this as well and I was surprised he didn't mention it considering he was a host on the former space scishow.

Well, the other Mercury required General Relativity because Special Relativity just wasn't enough.😁

It's probably a lot less of a coincidence than you think. The namesake of both Mercuries is the Roman messenger god, and the reason they both are named after him, is swiftness. Mercury the planet being the fastest moving planet in the sky, and mercury the element being the element that flows fast as a liquid at room temperature. They both have being fast for their class in common, that earned them both the same namesake, and it is their speeds that cause relativistic effects to come in to play.

@@carultchThe planet Mercury doesn't move fast enough for relativistic effects to come into play. Its average orbital speed is about 47 km/sec. General relativity comes into play for Mercury's orbit because the Sun's gravity warps space enough to affect Mercury's orbital precession. Every planet, and indeed every body orbiting the Sun is affected in a similar way, just less strongly than Mercury.
Edit: As a couple of people have pointed out, I mistakenly wrote special relativity when I meant general relativity. Thanks for the corrections.

@@JarrodFrates Still, it moves fast precisely because it is in a position where the sun's gravitational distortion of spacetime, is enough for relativistic effects to come into play. You wouldn't expect Uranus to have anomalies in its orbit that were explained by relativistic effects instead of another planet, when its orbital anomalies were used as a clue to discover Neptune.

I wheezed at " no no chemistry". Since today, this is the new, improved title of my toxicology books 😂

Liquid at room temp basically means there will always be vapor regardless if it's reached it's boiling point. Melting easily and boiling easily are basically due to the same thing although you still have to factor in polarity.

"No no chemistry" will forever live in my mental dictionary now

No chemistry?! What the fu... oh, 'no no' oh ok.

@@queefyg490 Gallium is weird though, with an utterly massive liquid range and boiling point of 2,400°C. IIRC the vapor pressure of gallium at 30°C is so low that it’s a probability of there being a single atom as opposed to a definable pressure value.

I'm a bio major and this one really actually felt intuitive!

Even I could follow the explanation.
Grade D "O" Level Physics (twice) ie failed twice to get the minimum C grade that is recognised as a pass.

I was wishing I had science teachers like this.

DPhil in Chemistry here, back in the 1980s. My reasearch involved the energy levels in uranium compounds (92 protons and electrons) so I'm familiar with d and f subshells and relativistic effects in the core orbitals, which I thought were explained well here.
My work was primarily experimental and my theoretical model was just a simple one involving only the outer electrons, but since then people with powerful computers have done the relativistic calculations and come up with answers that explain the experimental results.

If you have a degree in Physics you should know that mass does not change under Lorentz transformations but it is a scalar invariant and hence all this video makes no sense.

That’s another cool example of SR in chemistry. Thanks for sharing!

Interesting trivia.

@@McKaySavage I think it's also the reason why higher elements become more and more unstable... those speedfreak electrons literally twist spacetime so much that the atom itself is being ripped apart... the Roche limit of subatomic scales...

What about copper? It's a much lighter element

i heard its red shifting the light.

Healthy comment! 🎉

I wish I had heated discussions about the universe with my partner

Higher dimensions eh ... Talk to some Hilbert space dweller

Best is to remove one spatial dimension (or two) in order to allow for the remaining axis to represent time.

I'm jealous lol.

You cant absorb it though your skin, nor will it leave any dangerous traces.

@@donaldpetersen2382 quick skin exposure is one thing, but children playing with it unsupervised for hours on end I think that’s in unsafe territory based on the little but informative research I’ve done. 🫶

When I was in 5th grade I was in safety patrol and another kid used mercury he got from his dad to keep his badge shiny.

We used to play in it with our fingers during our science class. I remember how heavy it was when poured into the palm of your hand. Cool stuff!

⁠@@donaldpetersen2382i mean, you usually can’t, but that doesn’t make it *safe*.
it can get in through any minor, imperceptible cut or scrape
not to mention room temperature mercury can evaporate slightly and that’ll really mess up your insides if you inhale it too much or too often

And cost. I have a hunch that a pool of mercury might be ever so slightly dearer than a pool of water.

@@olmostgudinaf8100 One can assume that any science prof is going to be upset about the budget (this is a touch more reasonable than being annoyed you can't show off cool and dangerous things).

Dearer? Does that word have a definition I don't know about or was that a typo?

@@samstromberg5593 Not a typo, as any search engine can tell you.

@@samstromberg5593 It's typically more of a British English thing (not exclusively), but much as something can be loved dearly, it can cost one dearly, or be sold dearly. A dearer price is high or expensive.

Agreed seems like the more knowledge you acquire, the more questions you have

Every question answered should lead to at least one more question unanswered, but typically two or more.

Dunning-Kreuger, thy name is law.

Also Aristotle: The velocity at which an object falls is proportional to its mass

The puzzles of Dark matter and Dark Energy still loom pretty large. Likely I will never see those solved.

I remember a game show based loosely around that situation. I also remember arguing with my grandma about how lightning works because the knowledge and information access in her school years were more limited. I also still get tripped up by the knowledge that plate tectonics wasn't scientific canon until the 1960's or so. It just seemed so.... "It is known" by the time I was learning it, but it's contemporary to the US civil rights movement. Perception of time is wild.

I was in college around that time and it was definitely taught in the university intro chemistry class. In high school we only ever had the Bohr model simplified stuff.

I was hardly taught about subshells, either, in the U.S.A. I think that our professors considered them as inaccurate and outdated concepts in deference to the boundary-condition-induced quantum numbers so we got the atomic orbitals expositions.
I, however, was precocious so I had already learnt that from my Big Brother's collection of textbooks he had used. The Chemistry textbooks used the subshell models pretty effectively to explain chemical engagement between atoms. As I have a historical perspective, I tolerate thinking of electrons of atoms being packaged into subshells. After all, the Madelung (n+l) rule used by the Aufbauprinzip maps atomic subshells with electronic configurations' filling order pretty well (but not quite right all the way -- I'm not a chemist so I know anyway that I shouldn't trust my *historic* chemistry education 100%: trust *AND* verify.)
Electrons are delocalized waves as well as like tiny hard nuts. It just depends upon the resolution with which one looks at the electrons.
In superconductivity research for room-temperature ambient-temperature superconductors, electrons should be thought of as being delocalized waves (viz. Bloch waves) capable of being decomposed into Fourier series with a periodic coherence length that can extend its range to near infinity to achieve resonance.

Took me to first or second year of uni to finally understand. Think is you aren’t taught the Heisenberg model or principle of uncertainty till then because the Borr model gets taught instead as it’s easier to understand and works for the purpose intended. To be fair skipping the borr model would make it hard to understand Heisenberg

@@qazsedcft2162cause that’s all you needed. Bohr model is “wrong” but it works for the purpose intended and it’s easier to understand. I doubt you could easily understand the Heisenberg model if you don’t understand and work with the Bohr model. Unless you make the mistake of entering a organic chem class then it doesn’t really matter that much.

Yep, SR shifts the absorption spectrum of gold down into the visible spectrum, meaning it absorbs blue light but reflects red and green light giving it its yellow colour. The details are complicated but have to do with SR effects chaging the resonance frequency of the outer valence electrons.

Gold maximum phenomenon

It also gives it unusually high electronegativity for a D block element, to the point where it can even form anions, due to the relativistic speeds reached by the valence electrons

​@@Eden_Laika wouldn't SR redshift the light that Gold reflects? Gold is very good at reflecting Infra-Red and very bad at Reflecting Blue

@@davidaugustofc2574 Only if the gold was moving away from the observer. Red shift isn't a property of a material, but of relative velocity.

It's another name for Mercury

@@thenexttangle8568 I think BarononQuiply knows that His was a joke comment.

@@michaelhaywood8262 oh
My bad

There is good just rightly offensive joke there someone just needs to work it out.
It has to start somewhere..
Women are like the elements of the periodic table, the more beautiful, the more toxic.

“… Like a Ferrari with no engine. Fine as hell, but it just sits there and costs me money”

See, your ex was like mercury.
Mine was more like a dose of arsenic.
And she'd say I was more of an alpha particle. It's not dangerous until you let it inside you.

@@SimuLord SEE, your ex was like the alpha particle, mine was like the Big Bang. Incredibly hot… and just as dense

Pretty much most people’s ex.

Haha, that didn't even occur to me. 😂

Special relativity doesn't explain the orbit of Mercury, General Relativity does. Special relativity gives a negligible correction.

General relativity is also why gold is yellow. Without it, gold would be a boring, silvery color. It does a lot to make the world more interesting.

Can't blame special relativity for the aftermath of a Taco Bell meal.

@@Relkond Special relativity is what explains the color. It's a similar effect as in mercury.

Went over my head, please explain. Why is that controversial

@@robfut9954 Because the mass is not increasing in reality, although it is used as the most common explanation.

I was about to head to the comments section to be all "um acktchually" but I stopped because of that. Good save on his part.

@@omgsrsly @robfut9954 and the flamewar part is that there are a lot of working physicists who prefer the original interpretation....

@@thefaboo This will forever baffle me. Science is all about replacing old information that's discovered to be incorrect with new, *proven* information so that we as a species can progress in our understanding of the worlds around us.
To just reject new information smacks more of religion than science to me. You don't arrange your theories to come into line with reality, you re-arrange reality to come into line with your beliefs. No thanks. Stopped that decades ago now :D

😂😂😂

I think we had the same dad.

I broke a thermometer when I was a kid who couldn't stop fiddling with things way back when they actually had mercury in them, and have always wondered how much of my personality is a result of playing with the little shiny balls rolling around on the tile floor...😮

@@fumfering same here! nowadays they call for a hazmat crew.

@@Jefuslives I was too young to remember, but my older cousins told me when they buried my grandfather, they had to use dynamite (which was available at the farmer's co-op when Dad was a kid), and we were given lengths of fuses to play with. Light one end and when it got to the other, small bang.

The way he _generalizes_ makes me feel _special_

all made possible by post malone's brother too its crazy!

It's suffocating, actually. It makes one long for extinction in the wave function of a large, copper conductor.

Yes, 40 degrees C and 40 degrees F are the same temperature.

@@Fazzel no joke, that's where I first learnt about linear graphing.

Units are important. There are more than two temperature scales.

@@Fazzel No. 40 deg C is 104 degrees F.

I think you mean -40 deg C is equal to -40 deg F.

You had to step all over it for us lay folk, didn't you?

​@@melodyszadkowski5256dude I didn't even understand the correction. Maybe I'm stupid, but at least it didn't ruin my fun 😂😂😂

What are they considered then? An "other metal"? Didnt see any periodic tables with them labeled anything other than transition metals and I'm too lazy to try and find the IUPAC one you said.

Most periodic table sources still class it as a transition metal, while some combine it with the basic metals and call the group post-transition metals. In all honesty, the delineation isn’t enough of a mistake to call for a correction of the video’s efforts to educate, given the necessity to simplify anyway.

This reminds me of the classification of hydrogen and the problems thereof which they made four weeks ago.

Ga has an electron in an outer shell. Look at group 12. Also note that "room"/"not room" temperature is just a constant. For nature 0 and 200 degrees are not that different (add 273, the absolute zero, to both of them).

Yes! I've always wondered that.

Elements with even proton number also tend to be more stable than those with odd protons for some reason. Odd elements also have fewer stable isotopes.
Looking at it there doesn't seem to be any weird situation, normal β+ and β- decay. But other higher elements in the 53 to 57 nucleotide range show α decay, which doesn't happen again until 83 nucleotides, at which point it starts getting increasingly common.

Halogens are highly electronegative with a single valence vacancy, so they REALLY want that last electron. Noble gases have a full valence shell, so they’re happy as they are.

Yes because whenever we measure or observe the atom and its electron shells we are essentially "taking a snapshot" and freezing the electron in observable space so we can gain an ide and its spin and angular momentum.

"Incorrect" models can still be correct for much of what they model, which may be the important parts. It still makes sense to model electrons as point charges and point masses, provided you allow such things as angular momentum of 0 in some cases, i.e. that point either passing thru the center of the nucleus up and down or taking a figure 8 course. It's just a limit of our imagination, not being able to hold contradictory models in our heads simultaneously. But we know it works, because of such applications as NMR.

It doesn‘t. To be honest, I‘m fairly sure that the entire idea behind this video is wrong, as it is doing it‘s math with E=mc^2 which is not the correct formula for moving objects, the correct one would be E^2=(mc^2)^2+(pc)^2 or E=ymc^2 with y being the Lorentz-factor. Or for short: Relativistic mass isn‘t a thing.
So for short: The video really wasn‘t onto something at all.

Copernicium, the element below mercury in the periodic table is also assumed to be liquid at standard temperature and pressure. We just haven't made enough to observe that.

@@HappyBeezerStudios That's interesting. I had never heard that! I love trivia.

It's not a planet. It is a deity 😂

And the FTD delivery man.

coincidentally, special relativity was required to understand the behaviour of both the planet (it's orbit) and the element (it's orbitals).

@@ZurigaSungama its not a deity its the singer from queen

it’s also a car.

that's hard to do with 80 protons. Maybe start small with zinc?

Probably because the theory involves relativistic mass, which isn‘t even a thing anymore

Americium was named after America but it is pronounced Am Or Ree Cee Um instead of Am Air Ick Ee Um

@@Fazzel pity it wasn't Vesputium

Which ironically is much more faithful to the latin original. And, funny fact, his father was a copper merchant.

How are those two words pronounced differently? The pp sounds exactly like a single p.
Now I wonder if you're mispronouncing Copernicus...

@@LuisAldamiz It's the vowel before the p. Copper (like in "cough") vs Copernicus (like in "cup").

Remember what he said about the filled sub-orbitals? Tungsten doesn’t have those. The intermolecular forces are much stronger for tungsten. Remember, mercury is only held together by van der Waals forces, precisely because of its filled sub-orbitals.

@@eroraf8637 But they're all big enough they should also have the relativistic effects from the full f orbitals.
So they all should be a bit shrunken and have greater electron density, so the should be more repulsive toward each other than their one up the group neighbor.

@@mekosmowski I think you've misunderstood. The full f orbitals and the relativistic effect are two distinct contributions. Also, they aren't the only things that determine an element's melting point or material strength as a solid. You also have to consider the overlapping of different orbitals and sub-orbitals due to charge shielding and other such effects, but I'm not exactly an expert on condensed-matter physics.

@@eroraf8637 I'm not asking why the other transition metals of the period aren't also liquid, but why they don't have reduced intermetallic bond strength compared to their group neighbors from one period above, for example gold compared to silver (which specifically does seem to have reduced bond strength as evidenced by greater malleability, but this might be more a factor of crystal structure). Sure, reduced atomic mass is expected to reduce the relativistic effects, but it doesn't seem like a dozen or so protons and neutrons would be enough for such a dramatic change.

@@mekosmowski Like I said, there are other effects beyond just what's discussed in this video. Look up relativistic quantum chemistry if you want to know more. I'm just an astrophysicist, and I never took any graduate-level quantum or chemistry courses, so this is way beyond my expertise.

Subshells contract, not shells.

They don't get close due to electromagnetic effect, the contraction due to mass is an S/T warping effect.

Except we never will because a) it will very quickly decay into something that is NOT copernicium and b) the radiation released in doing so would kill/injure anyone watching and heat the sample so much it would vapourise. Understandably, most of the transuranic elements are somewhat mysterious and near impossible to study.

A pharmacy will probably take it along with other expired medicines for safe disposal. Or the battery disposal deposit at a recycling facility. Or a local school or college with a chemistry department. Or a jewellery workshop (not a jewellery store, but someplace that actually works with the metal.)

Scaremonger.

If you loved me half as much as I love you, you wouldn't worry me half as much as you do.

It's too unstable to exist at all for more than a few milliseconds.

predicted value of about 10°C... never determined experimentally of course.

I love that light bulb feeling. 🎉 Also, I agree--I hear the similarity!