Oppenheimer's Gamble - The Plutonium Crisis

Well, 40s anyway

yes, considering chat gpt hasn't already made a new groundbreaking proof

People seem to forget that machines replace simple tedious tasks, think of a bottle opener, could you imagine a factory opening and closing a million bottles in the 1800? I can, just take 100 people in a factory line doing 10.000 tasks a month, 333 a day, 26.smt a hour, for 12 hours everyday

(yes, doing algebraic calculations guided by a scientist is simple)

Yes, I was there, and I heard Von Neumann say " I wish I carried my laptop today".
He had left it at his home 70 years into the future.

Haha true!

Yes indeed, especially when it was human “computer” power too! Humans and slide-rules and adding machines. That’s how iterative simulation processes were often done well into the 1950s. And apparently some early models of IBM mechanical computers and card punch and sorting machine.
The US was desperate to get this weapon first, so any amount of effort was deemed appropriate.
The US was rightly scared sh**less. Because even if such a weapon was never directly deployed against the US, if Nazi Germany developed it first and simply held it as a threat, America also feared a total loss of Europe as a trading partner to a new fully “autarkic” Nazi-German ruled Europe which would have been disastrous for the future of the US.
It should be noted too that the Nazis ALSO had full access to proprietary (often custome designed) IBM computers and card punch and card sorting technology … and even clandestine technical support for this equipment throughout the war from IBM employees itself. This should have been a scandal, and still to this day few people know much about it.
I’m unaware if, or how much Germany and the Nazi scientists chose to use their proprietary IBM equipment in this way, to aid in physics, or bomb or rocket or aircraft design.
The Nazis have been documented to have used their IBM equipment to aid in their efforts to keep track of and to purge “undesirable” people of all kinds in the German state, and to organize the surveillance, detention, and shipment of these unfortunate people in a highly efficient manner to the “appropriate” work or death camp. Terrible. Scandalous.
To my knowledge IBM still hasn’t made a full accounting of this German activity themselves during WWII and has left it to independent historians and journalists to reveal how the company aided the Nazis and even took great pains to circumvent the slow-to-come US government regulatory efforts to stop their support of or doing business with an enemy combatant state that IBM executives were aware were using their equipment to design and enforce social policies that what would eventually come to be called genocidal.
I’ve not encountered any historian’s work on the amount of computing power supplied to Los Alamos and the Manhattan Project by IBM; it would no doubt have been quite helpful and much faster to run complex mathematical simulations of implosion on their proprietary equipment!

Truely, we stand on the shoulders of giants!

idk if id quite consider mathematical optimization as brute force, but would of been tedious AF

@@WelchLabsVideo attack ad-eminem and tu-quoque fallatio, your video is wrong and your argument is exposed

That is not a comforting thought

string theory go brr

@@trevordillon1921 lolll

“Assuming a spherical cow…” 😂

Well said.

von Neumann was literally coming up with the von Neumann architecture and pioneering the modern computer at this time. I’ve read that nukes and computers basically arrived as technologies at around the same time, as early computers were needed to solve all the mathematical and numerical problems on the Manhattan Project.
(Edit) Correction, not on the Manhattan Project, but after for making all the other nukes that were made after the war.

@@topdog5252 The ENIAC, von Neumann's first general-purpose computer, went operational in December 1945. It was originally designed to calculate ballistic trajectories of artillery. It was used for the nuclear program after the war, as there was no need to calculate ballistic trajectories in December 1945. The Manhattan Project relied on IBM punch card systems that were originally designed for business purposes.
After the war, the US nuclear program and the development of more and more powerful computers was highly interlinked. Even to this day! Guess who has the largest supercomputers in the world: The US Department of Energy.

Truly groundbreaking. ( no pun intended).

And with a timeline that would cause me to go bald within months. Urgency seems to be a paradoxical source of success for the government, as seen during the Apollo program as well. Give them an open ended goal, and they’ll take their sweet time.

People were so excited. They could kill hundreds of thousands of people with one device. What an accomplishment, they thought. People were impressed.

lol that's biggest "Either I'm right or it's no longer my problem" in history

That's one of my favorite non-fiction books. He really describes how the run up to fission came about, and how Oppenheimer, Kistiakowsky, Teller, Bethe came up with the design. How Seaborg synthesized/created/bombarded U238 to make Plutonium. How Fermi's "Pile" went critical. How Groves built cities of factories. But also how the physics of the early 20th century involved the Cavendish with Rutherford. Chadwich and the neutron. It's a fantastic read, and really describes how the 20th century came to be, as well as America's hegemony. He won the Pulitzer for it.

One of the best quotes!

Even the brightest minds have their YOLO moments.

​@@321sandspur3
😊😊😊I
Nomoo niloop
😅 0:15 ni
Mop mop ml

I was a Naval Nuke. The heat transfer problems are intense. The cladding problems are intense. The radiation problems are intense. And I barely got a taste of that (enough to be an operator).

He was a good mathematician, for sure. Not sure about his intuition as a physicist. Maybe he was misunderstood at the time, but the way we teach QM today (poorly) might have something to do with von Neumann's own misunderstanding of the physics behind the theory.

Good mathematician ? That qualifies as a supreme understatement . Who else but von Neumann had as much impact on so many fields as he did ?

@@michaelblankenau6598 Euler. Dudes... why do you have to prove that you don't know anything about the history of mathematics? ;-)

@@schmetterling4477 And why do you have to prove that you don’t know anything about Von Neumann ?

@@michaelblankenau6598 Awhh... Dude, now you are just feeling sorry for yourself. I will give you more attention anyway. You clearly need it. ;-)

Yeah, that feels like a trivial problem to me ... until, ... wait, what do you mean I can't use a transistor? Those aren't invented yet? So what the hell do we switch with? Glass tubes? Uhhh.

Yup they were fired by 4uF 5.2kV capacitors each piped into that coax by a KN-6 switching tube that was originally designed to be used in a strobe lamp. Now they have them with two laser pulses triggering a couple very well made shaped charges that compress a double paraboloid core into a sphere. Let us pray control over one is never lost. 🙏

@@christopherleubner6633what?

@@Gmoney00718 He's very clear in what he said.

@@Gmoney00718 big bomb got better. scary.

I know right!?

Yeah, functionally it's the same type of math, just being applied to sound waves instead of light.

That's far out that matter and light both can use similar lens logic. Makes you wonder if that is a coincidence or if it tells us matter is maybe not so different than light after all.

@@brokentombot I don't think it points to a relation between matter and light. We see this type of thing all over the place when we are dealing with what I believe are typically called emergent behaviors/properties, when complex small scale interactions give rise to more generalized large scale phenomena. I think it points more to the incredible power of mathematics (specifically calculus) and our ability to build models from approximations.
For example the equations that are used to model viscous fluid flow can also be used to model the movement of large crowds or traffic through highway systems. This doesn't mean that humans and cars are related to fluids in some way. The small scale interactions that are occurring between the molecules in a fluid, the people in a crowd or the cars on a highway are all obviously very different. To get the most accurate prediction of a fluid or crowds behavior we would need to be able to simulate each interaction between every particle/person, which would be incredibly complicated and is impossible for systems with a large number of particles. However we can make abstractions that can be used to approximate the large scale behavior such as how rapidly a disturbance (like someone getting shoved) will pass from person to person through a crowd, or how easy/difficult it is for people or cars to move past each other. These would be equivalent to the speed of sound in a fluid and the fluids viscosity respectively. By observing crowd behavior and traffic data we can make these abstractions and apply the same types of equations we use to model fluid and get very good approximations of a crowds behavior or traffic flow.
So it's not that light and matter are in some way similar to each other, rather the emergent behavior of light wave propagation through different mediums and the emergent behavior of sound wave propagation through different materials both fall under the same problem type and can be modeled with the same category of equations. What causes these behaviors though is vastly different.
Sorry for the obnoxiously long reply, numerical methods (computational modeling, or just using math to simulate complex system behavior) is a passion of mine, it was hands down my favorite subject when getting my engineering degree.

The irony is that newer ones use a small q-switched neodymium yag laser to trigger the implosion. The laser is made by Kigre corporation and is the same one used in eye surgery lasers for treatment of glaucoma. The laser pulse is delivered to the explosive directly that detonates as an acoustic wave shaper converts it into a structured force pattern, as you said is very similar to optics. The beam is split to 3 beams. 2 hit the implosion mechanism while the third one hits the explosive on the back of the neutron generation module. The design is 💯 percent fail safe, no risk of mistake. Security on the other hand. I truly hope they do not lose one of them. In theory it could be hot wired using the guts from a cheap camera flash unit.

Came here for the same thing.. (also it was even worse, it was √ (x²+[y-h²(x)] ) not √ (x²+[y-h(x)] ² ) )

Didn't want to say anything. Glad, you said it bro. Right, guys?!?!

🤓

as a nuclear weapons tech/engr.... I love you math guys! It was always my weakest link.

🤓

Glad you enjoyed it!

​@@WelchLabsVideoDo any of you productive people ever have to struggle to develop any memorizing methods (like zettelkasten or some other fancy note-taking system) or is accurate memory as natural as breathing to you? Furthermore, do you ever struggle to understand something for a longer time or is clarity and sharpness of thought also natural and effortless?

Yes! I was thinking exactly the same thing!

100%

Yes. Now I dont have to watch the movie and give money to the leftist pedos in Hollywood.

Actually, when the calculations became too complicated for von Neumann, he called in Stan Ulam. At that time Feynmann was a prodigy but not anywhere near the level of either von Neumann or Ulam. Ulam invented the Monte Carlo method of analysis. He was also the person that found the flaw in Edward Teller's design of the hydrogen bomb which is why it became the Teller - Ulam design.

the story is the same even in digital cinemas
🤣😂🤣

Indeed. Sub added.

Thank you!

Thank you!

​@@OskarHersch if AP levels of high schools then yeah

Happy 80th birthday when it comes. It was Mick Jagger's this week.

Does your birth certificate list "P.O. Box 1663"?
--

@@personanongrata987 No. My birth certificate lists as my place of birth as 1Sandoval County Rural.” I think I may have been born too early for the famous 1663 designation. There are a couple of birth certificates in the small Fuller Lodge museum at Los Alamos, and both have birthdates after mine. Several years ago I had to obtain a birth certificate from the State of New Mexico for f a claim my brother, sister and I filed against the federal government for our mothers death from radiation exposure. That certificate simply states my place of birth as Los Alamos.

They jad bennn developing explosive lenses for other uses e.g. armour piercing shells.
The UK team contributed much of this from theur naval programs.

Thanks for watching!

Thanks!

Veritasium too, my guess is all of them are trying to capitalize on the release of the Oppenheimer Movie

@@jamcdonald120 I was specifically talking about the explosive lenses. Did Veritasium make one about this too?

@@mickeyhage Nope. He glossed over the technicalities and focused more on Oppenheimer himself. If you haven't seen it it's actually a rather good biography.

At least 5 or 6 other YT''ers did., even theGrahamNortonShow ..also an interesting long-form take from U_Minnesota th-cam.com/video/_TQJEMC6mkk/w-d-xo.html (thank me later). Too much of a coincidence for this to be unrelated to the movie-launch; but did the movie-studio ask these science-influencers to create the videos, or is it just the zeitgeist? We shall never know ;)

Awesome thanks for watching!!

Guy was such an absurd legend.

Many says he was the smartest man ever walked on this planet.
When Nobel prize winner Jenő Wigner was asked how it felt to work with so many genius like Einstein, Heisenberg, Fermi, Bohr.. His reply was epic: I only knew one genius: Naumann

my videos have more detail i bet

he said "by the summer" , not "by December", I think

@@hobbycatkid I think you're right as this happens right before the Potsdam conference of 17 July 1945

it sounds a lot like "December", but I'm pretty sure he's saying "the summer"

Yes, I've watched several TH-cam videos which have clearly explained stuff that the movie I watched on Monday, glossed over. And when they did explain in the movie, it was basic, GCE O-level physics I did 50 years ago. Thank you TH-camrs for your videos

I was disappointed that Apollo 13 never mentioned how hydrazine is made.

When Manhattan project scientists started to work on the bomb, they also thought that it would be as easy as wrapping some explosives around a shell of nuclear material. The idea was to collapse a tube of plutonium into a ball and make it super-critical. All this stuff with compressing plutonium, explosive lenses etc took enormous effort to figure out -- it was not obvious at all even to a bunch of these best in the world scientists.

Check this one out, it's much better and quite a bit more historically correct (I'm a physics prof). I'm getting sick of everyone on youtube over-crediting Oppenheimer:
th-cam.com/video/H1QuZ6nsC68/w-d-xo.html

@@cogoid yes, absolutely. People really underestimate how many scientists actually worked on Trinity, and the interesting thing is that so many people made necessary contributions to the function of the bomb.

He also learned "Game" from a Master. Before any but a few knew it was a thing.

he did NOT , the engineer mcdonald raised issue and RF just demonstrated it on TV

@@nlcatter Factually, it was Donald J. Kutyna and Roger Boisjoly who steered Feynman towards the faulty clevis design. Sally Ride gave Feynman a peice of the O-Ring. He was the one who masterfully managed the ice water and C-Clamp demonstration so a non-technical person could understand what happened in the cold weather.

@@retiredbore378 Am I correct to say that a similar problem was found at Boeing after a couple of newer model planes crashed? Management and sales had promoted a product (to the delight of executives and shareholders) that engineers had serious doubts about. Serious enough that internal document trails revealed quite a dark streak of gallows humour concerning the safety of the aircraft, concerns that were shown to be well founded.

Thank you!

Nice! Hard to play?

@@WelchLabsVideo I think it's hard to get the subtleties right. I play it a lot more rubato than I usually hear it.

Will do my best

when you watch the movie you’ll know👍🏾

Oppenheimer was against the "Super". Teller pushed the idea after the war ended. I love the Teller interviews.

Oppenheimer feared the creation of a US hydrogen bomb would encourage a more feverent and dangerous arms race. Despite initially supporting the development (or rather not being opposed) he thought about the trinity test and the subsequent deployment against Japan, and thought something like a bomb 1000x bigger than that would destroy the world

@@maleprincess62 he might one day be proven right too.

Famously opposed the Super - he foresaw the Cold War arm's race that continues today.

James Tuck was a British physicist assigned to the Manhattan Project at Los Alamos. Tuck knew von Neumann was working on shaped charges for the implosion design, and is the person that suggested the explosive lens design to von Neumann.

@@buckhorncortez The French went on to develop their own independent A-bomb program- but they didn't have anyone at Los Alamos, did they? (or any spies like the Russians to pilfer the data)- how did they do it?

Yes all the Brits that helped the project gets airbrushed by US so it we're led to believe that the Brits contributed NOTHING to the bomb!

They are tubes called krytrons and sprytrons. They can hold off a lot of voltage and can turn on very quickly. The krytrons are krypton and hydrogen filled devices that create an arc like a thyratron but quickly. The sprytrons are similar but have a vacuum inside. When fired a fine plasma is created from the two trigger electrode pins and it causes a vacuum arc inside. These are quicker than krytrons but are one shot devices.

@retiredbore378 sounds like EG&G part number KN-22. Krytron tube. Had a similar issue with them for a holographic laser service set. Was used to fire off the electro optic q switch module in it. Were irreplaceable for the application too. Two shots user determined of 4nS pulse duration by up to 1mS separation.

A lot of that help came from Klaus Fuchs.

I think most people understand this, although a lot of people still vote for Trump

Critical mass is the MASS NEEDED to sustain a nuclear chain reaction. You can lower the critical mass needed by condensing the material, increasing its density. So you basically are compressing it to a critical mass because by compressing it, the critical mass needed is lower. Critical mass in and of itself is not a unit of measure.

You are compressing it to a critical density in a bomb which is a relationship of the surface area to the mass of the nuclear material. This is to reduce the number of neutrons that escape through the surface and thus allow them to engage in sufficient numbers in fast fission chains to allow a nuclear detonation. During the compression the mass does not change, just the shape and the density.@@aarong8457

I'm with everything except the part about "you see that solid metal ball? It's made of some of the densest material known to man... And we're gonna squeeze it perfectly to a fraction of it's size"...
The water in the hand thing was good but I think a little short ended - would have been useful to remind there that water is deemed incompressible... And something even *less* forgiving is in play.
Obviously that shit works because that's the only thing that changes to set the damn thing off... And they definitely go off 🤣

Thanks!

You seem to be educated on the topic. Is what you describe the reason why nuclear reactors improbable to explode and the worst case scenario is a meltdown instead of explosion?
I believe this has something to do with the isotopes as well. If so can you elaborate what actually makes certain isotopes favorable to explosion/meltdown (bomb/not bomb). For example certain isotopes are best for bombs and certain are for nuclear reactions

@@rinkashikachi Yes, nuclear reactors are susceptible to meltdowns, which may lead to other types of explosions, such as the steam explosion at Chernobyl. However, they are not going to explode like a nuclear weapon because of some of those reasons I mentioned. That does not mean that there won't be any explosions from a reactor or that a massive amount of radiation won't be released in the event of a meltdown. I only mean that true nuclear explosions do not happen unless the supercritical mass is weaponized. A lot has to go right for a true nuclear explosion to happen, which is not really possible in the configuration of a reactor. There just isn't enough time before the core comes apart for enough fission generations to proceed in order for all that energy to be released as an explosion.
Your question about isotopes is a pretty complex question. I probably have an above average knowledge of nuclear physics than the general public(I have a PhD in a somewhat related field), but I am by no means an expert, so take this with a grain salt. Generally, both fission reactors and weapons still use the same isotopes (U-235 or Pu-239) for their fissile fuel. However, weapons grade U-235 is highly enriched, meaning there are very few of any other isotopes present in the material. On the other hand, reactors use the same U-235 isotopes but the fuel is not enriched to nearly the same degree. Since there are other isotopes still present in reactor fuel (primarily U-238), these will absorb neutrons without fissioning and thus slow the overall reaction. Generally, I believe they want the core of a reactor to be oscillating back and forth between criticality. Whereas for a weapon, you have to have the reaction go as quickly as possible. Even with highly enriched U-235, this most certainly won't happen on its own. That is why the MP had to use things like tamper, which kept the core together for a split second longer using its own inertia before the reaction blew it apart (it also reflected neutrons that would otherwise be ejected from the core).
Using Pu-239 is more complicated since it does not exist in nature, and is either synthesized from Uranium beforehand or in real time within a reactor.
Finally, I should mention that fusion reactors are sort of the desired future technology, as they do not release fission products and can produce a lot more energy efficiently. These will use different fuels altogether, usually light isotopes like those of hydrogen. To my knowledge, these are still a long way off.
Again, I am no expert. I am happy for anyone to correct any error I may have made.

The sentence you quote is taken out of context and is also badly worded in the first place The issue was the Plutonium-240 impurity in Plutonium-239. The supercritical configuration needs to be assembled extremely fast to prevent a pre-detonation caused by the Plutonium-240 impurity before the assembly is finished. This made the gun-type design infeasible.

Nice

A person might not know how to speak and still can intuitively understand many many different concepts.
Ive heard that quote and variations credited to various people but it's just stupid

That quote is due to Ernest Rutherford, and was originally, "An alleged scientific discovery has no merit unless it can be explained to a barmaid."

​@@jsalsmansounds like the main goal of science is partly to impress the people of your preferred gender 😅

​@@maticz3923it is indeed pretty stupid.
I know a lot of derps that can explain how something works without having the first clue 🤣🤷‍♂️

@@jsalsman That one i can get behind
Science communication is important and yet extremely hard.

The mathematician who invented the Monte Carlo method was Stan Ulam. Ulam was also the person von Neumann requested to be assigned to the Manhattan Project when the calculations became too difficult for von Neumann.

Thanks! Yeah I love working on ending vibes.

There is nothing moral about using the A-bomb ... it is inherently an immoral device

That's because the movie, "Oppenheimer" was based on one of the biographies of Oppenheimer, "American Prometheus: The Triumph and Tragedy of J. Robert Oppenheimer." It's Oppenheimer's story within the Manhattan Project and his later life. If you want to learn about the entire Project and the development of the atomic bomb, two books are very good. The first is the classic by Richard Rhodes, "The Making of the Atomic Bomb." The second is more focused on science, "Manhattan Project: The Story of the Century," by Bruce Cameron Reed. A third is "Racing for the Bomb," by Robert S. Norris is also very good.

Thanks!

The problem is that the fissile material, whether uranium or plutonium, doesn't really want to explode. It wants to undergo fission reactions, but only so long as it remains a critical mass. The only way to get it to explode is to reach a supercritical state so that the number of fissions increase exponentially. If it's not held in that state long enough, it begins to undergo thermal expansion and blow apart before enough material reacts to get that big blast and mushroom cloud. Even when done right, at least in those early devices, most of the material did not fission. Something like 2 out of 141 pounds of uranium in the gun design and a bit more than 2 out of 14 pounds in Fat Man. It is truly amazing they managed to pull it off back then.
The reason we did and the Germans didn't is that they didn't pour the massive resources into the problem early on enough. It required enormous infrastructure to produce those small bomb cores and armies more to sort out the technical problems of explosives and detonators etc.

@@kenofken9458 ah I didn't know that either. I read a kid's simplified science book when I was 7 which said that the hard part is making the material but once you put enough together in one blob it will be a massive chain reaction unless you slow it down with graphite. One of those pieces of grown-up knowledge that upon examination, turn out to belong to a child. e.g. how it was extremely important not to walk into mummy and daddy's room without knocking on Saturday morning because they need their extra sleep

Thank you!

A factor not mentioned here in Pu has a huge number of possible crystalline configurations at room temperature. This makes it's material properties really hard to predict. Oh, and as it degrades it changes as well. So a functional mass doesn't stay functional. Good times.

I know right!

@@WelchLabsVideo the bulk modulus of Pu is around 30GPa, so IIRC a 1% change in volume requires a pressure of 0.3GPa. If conventional explosives have a detonation pressure of 5-10 GPa, then up to 30% volume compression is plausible (assuming linearity)
Question: do you know how much they compressed the Pu to make it critical?
Note: Pu is soft!

Scientists of the Manhattan project did not know, or rather, did not think, that metal could be compressed in an explosion. They started using explosives simply as an alternative to using a gun for throwing initially separated pieces of plutonium into one compact mass. It took five months before a few of them realized that pressures during these collisions were so high that it caused metal to be compressed non-negligibly. This was a huge surprise to everybody, and once Oppenheimer was told about it, the whole program pivoted to working in this direction.
It took another whole year before they figured out that it was not even necessary to slam the pieces together, and that merely setting the explosives off around a solid piece of plutonium was sufficient to increase its density *enough* for exploding the bomb. This became the final design, because it was the easiest to get right, and also to understand and to do calculations for it.
This may seem simple in retrospect, but in reality it was not at all obvious even to a bunch of Nobel prize winning physicists. It took them quite some time and some luck to figure all this out.
Regarding the actual pressures -- since it was not a plane shock, but a converging one, the pressures were way higher, in the 500-1000 GPa range. But you cannot use bulk modulus at room temperature and small pressure to calculate compression of plutonium in these conditions. It was still considerable, of course, more than doubling the density of the metal.

@@cogoid wow thanks for the comprehensive explanation!

von Neumann was pursuing shaped charges and James Tuck is the one that suggested the explosive lens design to von Neumann. Kistiakowsky is the person that suggested X-ray photography of the explosives as he was familiar with the technique from other work. He replaced Neddermeyer as the head of the E Division in 1944 and is the person who selected Composition B and Baratol as the two explosives to be used. Kistiakowsky did the quality control on explosive lenses used in the Trinity Gadget and Fat Man bomb. He drilled into the lenses to fill voids that were found by X-ray and filled the voids with liquid explosives.

Thank you!

Thank you!

YES! I would have loved to see that scene recreated in Nolan’s “Oppenheimer”. It’s a graphic, vital example of trial and error methods needed to bridge the theory to workable engineered design-gap. This video, I think, constitutes a refutation of one leading objections to dropping the A-bomb on an enemy city. And instead, doing a demonstration for the Japanese on an island off-shore. The ultimate objection? What if the promised super-weapon proved a dud? With only two bombs after Trinity site testing to gamble on the entire mega-show? THIS was an amazing feat of ingenuity. As the video says, not all indicators signalled that the detonator would work. The fact that some 20,000 detonation spheres were in circulation is indicative of the Herculean task needed to be swiftly brought to completion before it could be a “Go” mission. I am amazed at these people. The size of these tasks, and the pressure of their deadlines. Only weeks to months before the fateful invasion of Japan.