That's how Gallium is afraid of Bromine 😱

7:56
Gallium: now I have a GaBr3 protective crust on my surface.
Water: well yes but actually no.

1) bromine reacts with water to produce hypobromous acid that by reacting with gallium produces hydrogen bubbles on which gallium floats
2) gallium reacts with bromine to form gallium bromide that dissolves in water and so taking gallium away and then gallium, being liquid, moves to the now empty spaces
These are the possibilities that came to mind to me

The strange effects with water will likely be linked to hydrolysis of GaBr3. Do you see a temperature change?
Perhaps adding some GaBr3 to water would lead to similar effects close to a surface.
I wonder, what happens in saturated solution of HBr. Then the driving force should be gone (or been replaced by something different).

I too, am afraid of bromine.
Still doing undergrad chemistry, worked with it once. Lab demonstrator definitely let us know to respect it, we had the fear of God (bromine) put into us.
But I will work with bromine over HF any day, no bone hurting juice for me thanks

Fascinating. Can't help but think there's an interesting battery chemistry hiding in there.

Insane, never seen before, unspeakably nice shots and quality. U just wont stop surprising me :) Keep these cool chem vids coming

All I could think at some points was "Stop torturing the poor baby T1000!" XD

It looks like you have a new Chronos hi-speed camera. And it looks like you need to remember to do the black level calibration each time you change the settings. That will get rid of most of the vertical stripes.

The macro+slowmo shots are insane! More, I need more of it!!

Wow! Definitely reminiscent of the "beating heart" gallium reaction, maybe similar mechanisms behind it? Idk much about it but I'd love to learn how the gallium moves in response to the bromine's presence.

I think this is due to electrical charge. When the bromine reacts with the Gallium at first it does not form GaBr₃ as one might think. First it takes up electrons and forms Br¯, but the Ga⁺ is still in the metal, the positive charge is delocalized. Now the Ga⁺ has do leave the metal. I think this would mainly be happening at the Gallium-Water-interface on the bottom of the drop creating a charge differential between the top and the bottom. The water then moves with the Ga⁺ to equalize the potential and *somehow* this moves the drop. The heat this reaction creates keeps it liquid...

It feels so alive and sentient.

I like how gallium drops are actually shaped like cartoon drops

Okay, that's a cool effect, especially the water drops flowing over the galllium drop.

In the petri dish you can see the little droplets of gallium sort of chasing the trails of residual bromine, and the big gallium puddle suddenly move towards a bromine rich region as soon as it makes contact. It makes sense that reactants would be electrostatically attracted to each other at the molecular scale, but this is the first time I've seen it happen at a macroscopic level.
At the end of the video it looks like the gallium is going around drinking up all the bromine around it.

Beautifully cinematic.
Choosing to add music was a good decision.

I *really* want to see a 4-channel oscilloscope, synched to the slow-motion, where one electrode is an ohmic bond between the probe and the gallium metal itself (buried with an inert insulator so no other metals are exposed), one is a neutral counter electrode in the aqueous layer, and the other 2 are bromide and proton sensitive ionic electrodes.
As an electrical engineer that would be my first guess, to check the electrochemical potentials, altough admittedly it is probably more likely to be a surface tension effect together with some sort of non-stoichiometric compound/'alloy' forming with different physical properties from the base Gallium. Maybe it even acts as some sort of bromide/tribromide ionic conductor?
I would love to know for sure though.

Thank you for explaining these experiments in clear, understandable ways. Some of the chemical names go over the top of my head, I've never heard of some of them! I love the different colours and vapours or mini explosions in one big one, it's fascinating to watch.

Holy moly, I've never seen something like this! Amazing photos, quality, sound, montage, and experiments... WOW, even simple things look magickal!!!

Thanks, Felix. You're doing a great job and keeping us all intrigued.
I certainly appreciate it, Sir.
Continue

Before 7:00: This is beautiful and serene.
After 7:00: *EXPLOSIONSANDFIRE*

Pretty sure these comments have the highest % Nerd Concentration of any video on TH-cam at this moment. Nice one Feliks 😁👍

The slowmo footage is incredible! Your videos had such great film quality from the start, so it’s amazing to see you somehow improving on that!

This entire video was so stunning to watch, the footage, explanations, and even the music just works so perfectly together. Well done 👌

Legend has it that the gallium is still screaming to this day.

So my theory with no chemistry knowledge besides all the things I watch on youtube:
The bromine vapors likely caused a gallium tribromide film on the surface of the gallium, causing bubbles that are creating a gas byproduct and propelling them across the gallium surface. As it gets to the other side and makes contact with the water, the water likely reacts with the tribromide, stripping it from the clean gallium and allowing the clean gallium bubble to be reabsorbed into the main mass of gallium under the surface. Am I right? Did I miss something? Do I finally get that cookie everyone keeps talking about?

Returning from not watching for some time due to exams, damn, the production quality is amazing! :) Well done!

This effect of bromine and gallium is facinating.
I imagine when a small amount of water is added, it catalyses the reaction, dissolving the forming bromide, allowing the reaction to progress faster. This is how I think the water encourages the effect,
but why the effect is there in the first place I have no idea.

Many things going on here. 1. Gallium bromide is a solid, so with just gallium and bromine it deposits on top of the gallium, forming a rigid structure. 2. On the other hand, Gallium and just water together do not react very good. 3. Gallium bromide is soluble in water, this means the water removes the solid gallium bromide. 4. The surface adhesion of water to glass is higher than the surface adhesion of gallium and glass. That means that the gallium is gliding on a water film. 5. Now for the main thing, the movement due to the bromine. The reaction of gallium with bromine is of course exothermic and releases energy. If it where more exothermic, the gallium would explode, also "running away" in a way. Here the energy released is just sufficient for slow movements, with the water providing an enviroment of nearly no friction.

That was wild! So cool. Really enjoy your videos

This on took me off guard...
Great video... 😌

Again, great video.
It definitely looks like a "beating heart" experiment, so it must consist of a metal surface mechanism. My guess is as follows:
1. Br₂ reacts with Ga forming at first GaBr₃ on the surface
2. The compound, initially solid, forms a crust, a "protective layer" on the surface of the Ga drop, changing its surface tension
3. GaBr₃ , as almost all trihalides, is quite sensitive to hydrolysis, so it decomposes to some soluble, more water-stable products, like Ga(OH)₃ or Ga(OH)Br₂ and HBr. All these products go away from the surface, hence removing the "GaBr₃ crust"
4. As the Ga momentaneously loses its crust and goes back to liquid Ga on its surface, the surface tension changes again, creating motion on the grop.
5. If there is no "active bromine" left (Br₂ or Br⁻ with low pH), the beating mechanism stops. But if you put more Br₂ and/or generate more HBr in the aqueous solution, the GaBr₃ formation will restart the cycle, therefore sustaining the "beating heart".

TIL: Gallium drops look more like "cartoon rain drops" than actual rain drops :P

It looks like the gallium moves towards the highest concentration of bromine

Totally amazing! Never seen anything like this! But to me it seemed like it was attracted rather than repelled.

Thanks for uploading. Really love your videos.

The slow motion close up was my favorite part. Awesome video!

If you said this was life from another galaxy, it just might go viral. LOL

would be interesting to see if there is a temperature change, it also looks like its gobbling up the bromine.

Like water, gallium is diamagnetic, shouldn't be affected by electrical fields. Can any residues from introducing water after bromine create a film on the glass? This is interesting.

Love the video, keep up the amazing work!

Great content! I've a newfound appreciation and curiosity for this element's properties.

And that's how the gallium do.

What I see is a dramatic change in surface tension and the gallium is not afraid at all of bromine, on the contrary it seams like he is attracted by bromine. This is a very interesting and fascinating experiment.

Bromine trying to break gallium but gallium refuses to break

Oh... so in Terminator 2, Sarah Connor just needed some bromine to destroy T-1000

The music and slow-motion are awesome together with chemistry

Gallium in liquid nitrogen be like: prprrblblblblblblblblblbblblblblblb

Bromine reacts with hydrogen bromide, Gallium Gets cleared of its oxides. Bromine also reacts with Gallium, creating a layer of resulting salt:
3 Br2 + 2 Ga → 2 GaBr3
Which reacts favorably and exothermically with water heating gallium up which increases surface tension and lovers viscosity making shiny beads.
The dissolving/reacting salt attracts water to dissolve itself and because of the Br2 gas stream coming from one side water drops are pulled more from one side and floats towards crust formed all over the Gallium bead until it gets saturated and drops into “bulk solution”. Br2 gas stream contact location and metal bead form defines water “stream” behavior.
Just a speculation.:?

Bromine is such a badass bully

Gallium introduced to bromine knows not to relax again.

Well filmed and fascinating reaction between gallium and bromine vapor. I also thought of the Hg/Fe/MnO4- "beating heart" demo. I think that in this case the clean gallium surface reacts with the bromine vapors to form a thin layer of Ga2Br6, which then dissolves and ionizes to Ga(H2O)6+++ and 3 Cl- , probably with a high enthalpy of solution, to provide the mechanical energy observed.

Please have a collab with TheSlowMo Guys 😍

Ah yes Gallium, the dirtiest metal & the hardest to clean up.

7:30 I feel sad for this gallium falling down. He is looking his friends dying

Someone wanted to show off their new High-speed camera :D
Wonderful shots, looks amazing.
To your questions: (haven't looked in the comments on purpose)
1. The drops running over Ga are probably water droplets dissolving GaBr3
2. Since the Ga definitely was a little more pasty, I instantly thought of sodium amalgam. So this was probably Na in the Ga that reduced it instantly and therefore the drops did not show the weird behaviour.

Your footage demonstrates the opposite to what you say. Gallium was attracted to bromine in water. It was moving to the higher concentration of bromine and if you watch carefully you can see it discoloiring the whole solution by moving towards more reddish parts, consuming the dissolved bromine by converting it onto salt and leaving relatively colourless solution behind. At 8:48 the drop literally jumps into higher concentration of the bromine like the terminator personage, but that's just the most epic moment. All the time it was attracted towards the beomine. Explanation is this: the surface of the drop towards the higher concentration of bromine gets stripped of faster resulting in surface tension decrease so the droplet deforms and moves to maximize the contact area with the bromine ions. Besides, the increase of gabr3 solution concentration may also decrease the surface tension of bromine even more, exacerbating the process, but the last part is not necessarily so.

2:42
That reminds me on the sintering process.

That’s pretty cool thanks for sharing

**=** So, the gallium metal is very bromophobic!

dude this should be top chemistry channel on yt

Truly amazing shots.

i think a lot of ppl underestimate music in this clips :D it's like watching top class movie in cinema :D

Gorgeous cinematography.

Just came across this channel today. Top quality content

The water wakes up the gallium which then realizes "That wasn't a dream! This bromine really stinks!"? Maybe? Do elements dream?

You get a very similar reaction out of steel when tig welding steel tube if you pull your ark away suddenly in the gap it's called a fish eye in the boilermaker trade and is considered a flaw in your root pass

Galium:liquid as mercury on your hands, but not toxic
Galium in YT vídeos: stonks↗️

The quality of this video is astonishing

The way the gallium is physically agitated just from some bromine vapor makes me think electromagnetics. Maybe the reactions at the surface generate some field which is propagated along the smooth surface of the drop and induces a current, which is turned in to motion by the thermal circulation of the metal?

Impressive, Slow Motion.. Would Love To See This In a Compress Vacuum On A Bromine Vapor Environment With Magnetic Levitation Because NASA Uses Gallium In Some Propellants for Electromagnetic Thrusters.. Would Make For Awesome Slow Motion Capture.

Very cool and absolutely beautiful footage!

The macro shots in your vids are great!

The interstellar OST would fit in so perfectly!

Amazing! Now I know more about their relationship :)

What a coincidence, I am also afraid of bromine!

I subbed up. Great stuff.

The gallium has PTSD. I also quiver and emit a stream of water in the presence of bromine.

Liquid fluorine + Decaborane

Surface tension from the water reacting to the bromine at the base of the gallium.

Seems like the highest concentration of bromine forms the gabr3 fastest and the crust is flowing towards the lowest concentration (or maybe repelled by the bromine), dragging it's surrounding with it and thus moving towards the highest concentration of bromine in the water (or just pulling water across the surface)

10:40 Here in this part (actually earlier when just all the water was added) where the answer to the title is. It's not afraid at all, it loves to gobble it up, and seeks it out

without slow motion a lot would be lost in the reaction , quite spectacular

PTSD in gallium is real

That’s how chemicalforce produces amazing content

Impressive slow motion!

Life is so very strange. To think we know many things but have yet to fully understand them is enough to make me feel very small in comparison.....

If you put gallium on one side of a petri dish with warm water and then put a small drop of bromine liquid into the other side I think you'll see the gallium Rush towards that side, because a layer of salt is forming that is lowering the surface tension on that side.

The banding of the Bromine concentrations lined up and touched the point where the drops originate. It almost looked like magnetic field lines connecting to a pole......

That gallium is hungry for bromine.

Poor galium being bullied and chased by mean bromine 😢

Wow, awesome slo mo

1:00 I was wondering what force is attracting the beads to the larger blub, as it didnt appear to be a current in the water. Had to look this up apparently gallium along with other metals have magnetic moments that appear and disappear rather quickly when solidified. Awesome stuff!

The dissolution of the GBr3 in water is adding thrust to your gallium ball. I noticed this in the slow mo where you could see the turbulence crawling across the surface. Beautiful demonstration. Did you know it would do this? I've seen the gallium heart before, but not this. I think this is cooler.

Somehow this made me think of a comic:
*Gallium saw bromine with a normal charge*
Man I’m not scared of that
*Another Gallium saw bromine with a positive charge*
Aaah!Im Positive I’m gonna run! 15:01

There are polar solvents and non polar solvents. Water is good for ions which the bromine wants to be. Gallium is to internally bonded to dissolve it well and can act as the separator of a battery where bromine is the anode and water is the cathode then the drop moves because of electric right hand ion

just amazing!!!!

No- get- away from me-

Very cool!!!

Very cool!