🔔▶ I’ve set up a YT membership option and Patreon for anyone interested in supporting the channel and accessing some perks, including more science insights! As you’ve noticed, I’m trying to adhere to a more regular posting schedule - 🪦RIP my christmas break, weekends and free time - so I’m grateful for your support and nice comments. www.patreon.com/totalsynthesis Thank you!

the fact that a molecule has "kek" in its name is just... wonderful

I love to see that those polycyclic aromatic hydrocarbons get some attention, as well as Diederich, who contributed so much to this field! Well done!

what if... supersuperbenzene! make a ring out of a bunch of these!

i really like the fact that you show both modern and old school syntheses

5:44 That Swiss pronunciation caught me off guard. The compounds covered on this channel are becoming increasingly exotic. And I love it.

Great video! Another example of an unusual aromatic compounds are carbo-benzenes. Carbo-benzene is a carbo-mere of benzene and it's basically a C18 ring where you have an alternation of allene and alkyne fragments (in contrast to sigma and double bonds of benzene). This topic was developed by Prof. R.Chauvin and his group in Toulouse.

How have I not seen your channel before?! I am a master's student in organic chemistry and I already know that I will love all of your videos! Keep up the good work :)

These videos are a gift. Thank you!

These organic chemists are out of this world. True genius

small knowledge like this will help me when I get to organic chem. I do really love chemistry more than any other subject.

As a kid with a passion for chemistry, but only just getting into organics, this feels like 70% random stuff and 30% "well I understood something at least" Great video btw!

how cool! I'd certainly think delocalization of all the electrons in the ring would make it more stable than 6 "islands of delocalization", wonder how stability of delocalization relates to the area it's spread throughout, and where's the cutoff when it's just too hard

I appreciate the discussion around the instrumentation.

Super interesting. I really appreciate all the work you put into this. I sometimes look back in regret that I never got a break as an organic chemistry researcher.

first video ive seen from your channel, but it was very good! will be sure to stick around for more :)

I've only taken ochem1 and my mind is blown! This synthesis is insane! Thank you for contributing this awesome content, and I hope the algorithm turns to favor you! Subscribed

Anyone includes Clar's work in their presentation clearly knows what they're talking about. Kudos for an enjoyable but seminar-like video. By the way I study the synthesis of carbon nanotubes and a lot of this is relevant to that problem and yet often ignored.

I loved this video. In my organic chemistry 2 class when we started learning arenes and aromaticity that is when I had my "aha" moment ! I was so happy to see I knew before mentioned that the newer method looked an awful lot like diels-alder. Thanks for the upload!

I know nothing about chemistry, but it still was interesting to watch

the pinnacle of onion rings chemistry.. awesome stuff and thanks for covering about it man!

Chemistry is so beautiful! Awesome video man! I'm also curious, is there any practical uses for kekulene or is it just a "proof of concept" kinda thing?

Incredible work at a point in history with no computer assistance by God these folks are brilliant!

glad to see you posting again brother

Wow! This is an awesome video. i I know only the basics of the basics of organic chemistry, but seeing such highly complex synthesis and depth of organic chem. blows me away! It gives so much motivation to learn more about this field of science! Apart from that, i adore and respect high-quality videos like this cause i can only imagine how much effort was put in it! Edit: It might sound silly, but i really like when organic chem compounds "power up" like benzen and kekulene. I remember when I saw a simple alkane called 2,2-dimethylpropane (Neopentane), and i was blown away how it looks like if you would put one C atom instead of each H atoms in methane and i was like "This shit is powered up form of methane!" Goofy, i know, but that's how my brain works 😅

Love your channel. Are you in any way affiliated with ETH/do you study/work there?

As always I am puzzled by your content. Interesting, educational and funny. And you even made the effort to show all your sources.

If benzene is fun, then this is top kek! And it's a really nice looking molecule.

High school student, loved this video

How about drugs with an adamantane substituent? Many have some interesting common properties.. And who the heck built buckminsterfullerine? Love your stuff my man

I follow, barely. This is beautiful synthesis.. I always wonder about exotic side products that get thrown in the wash container never seeing NMR or mass spec

Cyclopropyl carbonium ion is interesting. I think I made this in the SN1 solvolysis of 2-adamantyl compounds. Only got the exo-protoadamantyl product, i.e. nucleophilic attack from only one side.

"If you thought drawing benzene was hard, let me introduce you to superbenzene"

thanks for your efforts, I thoroughly enjoy your content.

I'm a working stiff in heavy industry but have just enough knowledge to get myself in trouble regarding the world of chemistry and I cought about 70% of the video thanks for explaining my knowledge

i miss chemistry like this... we barely have any in chemical engineering courses sadly

Correct me if I'm wrong, but the hydrgenation procedure you show in 5:08 states that Raney-Nickel was used, not Pd / C?

Wow! Looks I've found amazing channel! Like and subscribe. That's not a shitty tiktok and not a letsplay, but just really informative content.

I hope NileRed sees this and make some for the fun of it 😀

Can one combine 6 Kekulene-molecules in a hexagonal shape to create a fractal „super-kekulene“ and what would be its traits?

Great video as usual!

Perhaps it's more likely for there to be a net flow of electrons between 6 total bonds (in benzene) than through 18 (the inner path of theorized conjugation in kekulene). Maybe there are range limits to that kind of delocalization in nonmetals

You know, Hexagons are the bestagons. Why? Because bees. Bees are the best and build only the bestagon, the hexagon. Now, I know what you're thinking. Bees build hexagons because they're hexapods with hexagon eyes. How could they do otherwise? Excellent point. But the humble bumble has an engineering problem to solve. She makes two things: honey and wax. The former to eat, and the latter to contain the former. To make but a little honey, she must visit a lot of flowers. And to make one unit of wax, she needs eight units of honey. Wax is costly for bees in flower terms, and honey is drippy in food terms, so to make a hive that contains the maximum honey while using the minimum wax is royally vital. Thus, a honeycomb conjecture. Which shape works best? To answer, we need to talk tiles. Tiling is covering a surface with a pattern of polygons. There's lots of options because there's lots of polygons. Even the regulars go on and on-agon. Now for bees picking patterns, the more complicated ones obviously use more lines than necessary. That's what complicated means. And thus a honeycomb of that tile would use more wax per honey. So sticking to the simple regulars, there are just three that tile tightly. Triangle, square, and hexagon. Pentagons are broken hexagons that leaves gaps. Same with Septagons. Octagons are alright, but they're no hexagon. Which leaves the tiling trio which tile differently. A square is a square of squares, which is a square and so on. Squares tile tidily by basically cheating, covering an infinite plane with an infinite number of parallel lines. Like, wow, that's what a plane is. Boring! Triangles pull the same trick, dividing themselves into infinite nothing. But not the hexagon! The only regular polygon to tile a plane without resorting to debasing self-division, unlike some squares I could mention. At least triangle is trying to be more geometrically interesting than square, teaming up a bit to... one, two, three, four, five, six. Wait, hexagon! The other shapes can't help it. They just want to be the bestagon. Even some of the irregulars, like rhombus, tile by hexagoning. Same with your triakis tiles, and deltoidal trihexagonals, and your, ah, kisrhombille, and floret pentagonals. Look, they're all just hexagons. Even Cairo tiles (poor pentagons) tile up as best they can do to form a lumpy hexagon. The rest just can't compete with the best. The hexagon, nobly indivisible, is the bestagon. Uhh, where were we? Oh right, honeycomb conjecture. Max honey. Min wax. Three options. Okay, yes, there's the circle. A shape defined by the least perimeter for the most area, but that only works when you need just one. Pack circles and this is the best they can do. Look at all that wasted space! And even if you pack the gaps, you still use more wax. And again the way these circles, arrange themselves... it's almost like... onetwothreefourfivesix hidden hexagon! Bees use the hexagon because no shape is better to create the maximum area for the minimum wall. And this min-max stat of hexagon is one of the many reason they show up everywhere. Including in the aforementioned bee's eyes. Each hexagon is a long tube that leads to the light-catching cells at the bottom. More light equals better vision and hexagons let the most light in using the least amount of wall. So why aren't your eyes hexagons? Au contraire mon ami, they are L'hexagone. Not on the outside, but on the inside. Your light catching cells are at the back of your eye, in a hexagonal grid for the same reason as bees. Max light, min wall. Your window to the world, is but through the hexagon. Does that not make it the bestagon? Okay maybe hexagons as a min-max-agon doesn't catch your fancy. Then how about a little mystery, oui? Let us travel to Saturn. Yes, the rings are attention-grabbing, but leave the equator, travel north and here lies the unexplained. The Great Hexagon of Saturn. Need something for scale? Well, here's the Earth. Oh, here's six Earths. Saturn's hexagon is pretty big. What is it? Well, you might be thinking it's a geological formation. An enormous basalt column like the smaller versions you find on Earth. But no. Saturn is a gas giant. There is no surface or geology to speak of. So the great hexagon is composed of shapeless clouds somehow keeping shape and changing color. It's a magnificent solar system mystery. And, while I'm no space archeologist, if I was looking for an alien-gifted monolith, on the most "look at me" planet, under a hexagon beacon with earth-sized sides, that's where I would start. After all, what aliens would want to make first contact with the nearby monkeys before they became enlightened to pursue the universal truth. Hexagon is the bestagon. From the largest down to the smallest. Say for example, this tiny snowflake I happen to have, that have six sides, as all snowflakes do. Gee, what could cause that to be? Let's zoom down to the atomic realm and see. When water molecules join together to make a flake, the sturdy shape they prefer is the hexagon. As more molecules join, they extend the flake fractally up. The beauty of the snowflake on the monkey scale, is but an extension of the hexagonal perfection on the atomic scale. Okay, yes, you will sometimes find snowflakes with twelve sides, but this happens when two growing snowflakes get stuck together, so it still counts. And the hexagon isn't just for snow, but for all ice 1H, which means basically all ice on earth. Yeah there's a little ice 1C which we don't talk about because it's made of cubes, and cubes are boring. And there's a bit of ice 9. No, don't touch that. But if there is ice in your drink, give thanks to the hexagon for keeping it cool. And it's not just water. Lots of atoms use hexagons because... (take a note) hexagons are the bestagons. Oh, using a pencil? Get ready to have your mind blown about the hexagon here too. The lead. Well, it isn't lead lead, it's carbon. And you know what carbon atoms think is the bestagon? The hexagon. Pencil graphite is a whole bunch of hexagonal carbons, and when they happen to be in a straight sheet, that's graphene. Which happens to be the strongest atomic material in the universe. Some of which is in that pencil. To tear a sheet of graphene apart, you would need a hundred times more force than to do with steel. Hexagon is strong-a-gon. This is because when hexagons come together, they form three-sided joints 120 degrees apart. This, for the least material, is the most mechanically stable arrangement. Pull on one joint, and the other two equally pull back, push in, and the other two are the most able and stable to resist. Now look anew at a tiling of hexagons and you see it is composed of nothing but these max stable joints, each arranged perfectly to help the others be stronger and stabler. This is another reason hexagons show up everywhere. The universe blesses stability in her physics, from those basalt columns, to bubbles which, as soon as they can, ditch their spheres to become as close to the hexagonal perfection as they can. That's so cool. Oh right, yes. So if your pencil lead contains some of the strongest material in the universe how can your write with it? Okay, okay. This is going to get even more exciting. While hexagons are super strong this way, they aren't super strong this way. On a small scale, that means your pencil can break off in layers to leave a mark. But on a big scale, hexagons can be flexable while keeping their strength. Which allows us to create some totally unreal materials. Print out a grid of hexagons in whatever, from aluminum to cardboard, make a little sandwich, and pow! You've got honeycomb paneling. A ridonkulously tear-resistant material that's also super light and flexible. It's used everywhere but particularly in aviation. Rockets need to be strong yet light. Same for aircraft. With wings that really can't tear but also need to bend. And only the magic of the honeycomb panel can do both as well. Give thanks to the hexagon for blessing our flight. And we still haven't yet discussed the most important application of the hexagon. Games! For centuries there has been great debate over boards, squares of hexagons? Spoiler... hexagons win. Square boards are the first thing an unenlightened species would think of. They look sensible and are easy to implement, but they are terrible, ineffective boards that cause spatial suffering. On a square board move horizontal or vertical once space and you've moved one space, but move diagonal and the distance is the square root of two spaces. Gross. Diagonals warp the distance pieces move. Square boards look even and tidy, but it's deceit. Their diagonals corrupting the meaning of space and time, and of course they must, because a square only has four true neighbors. Hexagons, however, have six which is more than four, which is better! And the distance from once space to the next is the same in every direction. One space. Just as it should be. If you're a game based on squares, I'm so sorry. But there is hope. With thought and effort, you can hexagon yourself into a better place. As we all should aspire to do, spreading order and hexagonal enlightenment for, hexagons are the bestagons. And now that you agree, with your eyes will see their six-sided perfection in all things. And you will say to yourself, as part of the order, hexagons are the bestagons.

Those diagrams are a bit hard to understand. Some of the rings seen to have only one or two double bonds. Is there only one hydrogen on each of the outer carbon atoms with only two neighbors or do some have two hydrogens?

Can you tell me what's the easy way to find out degree of unsaturation ?

Fascinating ⚡️

I love Benny Zeine. The aroma of Phenylacetic acid as it couples with/against the cancer causing Benzene. Find how Peer reviewed info is golf clapping about Phenylacetic acid.

How do you get the benzaldehyde to combine with toluene? It doesn’t look very Aldol to me. Is that benzyl carbon electrophilic?

But is it possible to achieve the creation of the "Superkekulene"?

he's bacc :DD

I know the structure of benzene. Source? It was revealed to me in a dream

What are the thermodynamic properties and phase diagrams of kekulene?

top kekule

How plausible would it be to make a version of kekulene where every radial bond is dative?

Has anyone made any quinone like versions of this molecule? Has anyone studied it for photoredox electron transfer?

this must be the new "ligmasynthesis" every chemist has been talking about

RIP superaromaticity you were too based for this world man 😭

I wonder how many hydrogens and oxygens I can stick to this

praise Kek

So...get 2 molecules of kekulene and "stitch" them together into a torus - inner ring to inner ring, outer to outer.

I understood most words.

Why dont you make solid state NMRs with it?

Is there a 6 ring "bigger-benzene"?

Can u make cubic graphite

Omg! 🤯

i like your funny words magic man

When I saw the title I thought you were just being memetic or sth... then the name "Kekule" came up... I couldn't believe the name was actually "kekulene" until I actually googled it...

YEAH SCIENCE!!! 😃

At 2:30: (1) benzene (2) urchene (3) nazene

Make a chain with kekulene links!

5:13 "2.4 kg of Raney Nickel" is not something I expected to read. xD

finally, i won't run out of car fuel

All that work and they couldn’t take a picture of the green crystals?? Come on!!!

kekulene sounds like a anime power up for benzene like a super saiyen benzene

Please, if you have not, find the book of aqaruis.

Two videos in a month; is it Xmas or what!

imagine how many nitro groups can fit on that, it would be so explosive

I was literally joking about a benzene ring made of benzene rings a few months ago wtf i didnt know it was a real thing

“A Chad version of normal Benzene”

Watching this just because it may come in jee advanced.

Kekulene ring. Ok. Now make a ring out of the Kekulene rings. If that’s even possible, Idk man I just weld and fix stuff

Not every rings in kukulene is of benzene

like I came here for the science, but just 10 seconds in the video I must click like for the meme

Now I want to see it form sandwich compounds with chromium

KEK-benzene

So now, the solution is crystal Clar.

Meine Kraftstof is B E N Z I N E

wow

Wow.

My first time on your channel. I knew you were swiss at about 00:01! Greetings from a fellow swiss :D and thank you for the interesting video, i will stick around

is it yellow?😁

Mesomerie his father

Nmmmm😊

Wait until he gets to know about fullerene

hmm......

ANOTHER VIDEO?? :DDD

Put gigachad in thumbnail, must watch

Isn't Superbenzene the trivial name for [6]-Circulene? At least that is how it is in germany. Fun fact: [6]-Circulene occurs naturally as a rare mineral .... to think this fuck forms naturally is realy weird.

Super TNT?!?!?!