wow, thanks to you for supporting the channel! I really appreciate the gesture, for now I can only do my best to keep producing this kind of content. Thanks so much!
@@chriswanger284 Thank you for that information. I wish we were building more nuclear power plants in the US. Wind Generators and Solar Panels are just such bullshit. Americans have been indoctrinated into Global Thermal/ CO2 thought extremes which are clearly lies. Anyway, thanks for your communications.
@@chriswanger284 you are correct on that; however, there is a big difference between chain reaction and fission. The former requires the later. Szilard's patent does not point to a specific element for the chain reaction. Szilard didn't know which element on the periodic table (in any) would sustain a nuclear chain reaction, he only patented a concept. Still relevant. In fact, his research program was bombarding one by one each element of the periodic table but Hahn and Strassmann tried uranium first and discovered nuclear fission. The actual verification of nuclear chain reaction was only possible at the Chicago Pile with Fermi, closely working with Szilard.
"I could talk about Peierls for hours....." please do! There is a large and appreciative audience for your content.....formal physics education is wasted on the young 🤭
@@jkzero Just want to second this - he’s one of the particular ones who doesn’t have anywhere near as well-known a story/contribution as the big Manhattan Project scientists. British work beforehand on Maude/Tuballoys as well. And the Uranium Club and German institutions & scientists besides Heisenberg and his Bohr/Copenhagen peers. I was just watching a Teller interview on web of stories where he was mentioning how he and Mitzi (maybe just her if he was testifying to Congress) got to go on a sightseeing trip to Mexico with the Peierls’ and Klaus Fuchs after the Manhattan Project was ended before Teller was to start his new position at the University of Chicago. Interesting collection of characters for a vacation.
I just discovered this channel I'm in love with the visuals along with your intuitive explanations. You easily deserve 100x your current following. Awesome videos
great that the algorithm someone brought you here; I am glad you found the content of interest and clearly explained. Thanks for the positive feedback. Just curious, what were you searching that brought you here? Thanks for watching and welcome to the channel.
@@jkzero I was initally reccomended the "Math of Saving the Enola Gay" video on the TH-cam homepage and decided to watch a few more of your videos. The algorithm knows all 😇
great to know that my first video is so much recommended by "the mighty algorithm" and thanks for exploring the rest of the channel. It is very quite new but quickly growing, which motivates me to keep making videos. Comments and suggestions for topics are more than welcome. I cannot guarantee to take all requests but I am collecting suggestions for the future, if there is any particular topic you are curious just let me know in the comments.
@@jkzero Ahh, I didn't realize that it was your first. Thats a high bar to set for yourself ;p. Something I am curious about is the calculations behind the arrangement of high and low speed explosives in an implosion style warhead. I've definitely heard it mentioned in several places but I don't remember the keywords to search for.
@@amelted thanks fro sharing your interests, I have watched dozens of documentaries and videos about the implosion design and I agree with you, the whole idea of how to turn the high-explosive's shockwaves inside-out for the implosion is always glanced over. I have a video about the implosion design in the pipeline because someone asked me "how much is the plutonium core compressed?" and I honestly had no idea. I did the calculation and I now know, so I plan a video for that, maybe I should create one about how the explosive lenses work. Thanks for the suggestion!
Thank you so much for this very interesting video on Dr. Peierls and fission. I've read some physics history and was already familiar with the great physicists of the 20th century; I've even got a poster of the famous photo of the Solvay conference on my office wall. I was unfamiliar with the work of Dr. Peierls and now can appreciate how important a physicist he was not only from a scientific viewpoint but a historical one as well. I look forward to further videos from you and perhaps you can write a book some day.
great to know that you got sir Rudolf Peierls (he was appointed a Commander of the Order of the British Empire) into your list of important physicists of the past century, like Hans Bethe, Peierls is a legend of physics, but unfortunately his importance requires lots of concepts to appreciate and for the same reason it is unlikely to have films about them. Thanks for watching and subscribe for more content coming.
As a mechanical engineer, I was the only one to sign up for the full 2 courses in nuclear power at my small university. Fortunately, the professor allowed me to take the course as an independent study with the proviso that I do the reading and explain it before him. Never had I learned a subject so thoroughly.😂
Wow, that's a nice story; you have a point, when we attend lectures we expect the lecturer to do most of the work, if you are lecturing then that really forces you to prepare and learn. I am currently running a video series on the early times of quantum mechanics and I am using the original papers by Planck, Einstein, Bohr, etc, and I have learned a lot of content that doesn't make it to textbooks. Check it out, in case you haven't th-cam.com/play/PL_UV-wQj1lvVxch-RPQIUOHX88eeNGzVH.html
I was at university studying physics and maths in the early 1960s. I remember that one of our lecture courses was taught by Otto Frisch. The topic of one of his lectures was the discovery of the electron. He did not teach us about nuclear physics. That was done by somebody else.
Wow, that's a nice story, thanks for sharing. For what I read, Frisch kept a low profile after the war. Decades later he began sharing stories with his students about his life with Meitner, Bohr, and Stern. Only after retirement her daughter asked him to write those stories in a book. It was later publish as "What Little I Remember." I read it not long ago, it is a delight, I posted about it here th-cam.com/users/postUgkxtdfZmgblmHdpq2lY39GdI8IOGc92YmsT
A very good video, I gave a thumbs up and subscribed to the channel. Thank you for the great work. And yes, I'd love to see a video on the neutron diffusion equation.
Awesome, thank you! The video walk-through solving the neutron diffusion equation has received way more support than expected, great to find more people interested in the stories but also in the calculations. Thanks for watching and welcome to the channel
Thank you Dr Diaz. I am so glad to have found your channel. I am thoroughly enjoying the fission bomb videos. Will you be doing any fusion bomb content at any point you think? (I don't mean right away, just at some point)
I am glad that you find the content of interest, there is plenty to talk about fission and some bomb physics, but fusion could also come in the future, requests are more than welcome so I will keep it in mind.
Good morning Dr. Diaz. I am now a subscriber to your superb channel. I came to it because I have had a life-long interest in nuclear physics relating to the development of atomic weapons. I have some physics background as part of my former career as a radiologist. The explanations you provide are amongst the clearest I have heard. I wish I could better understand some of the equations you display, but since I don’t intend to manufacture such devices, I’ll take that information “on faith.” Despite having thought I knew the basics of thermonuclear weapon design, I was surprised to learn that the major part of the “yield” is not simply a function of the amount of lithium deuteride, but the U238 casing around that material undergoing fission triggered by the fusion. I am still not clear if determination of the yield of the bomb also still depends on the amount of lithium deuteride, but hopefully that answer will be forthcoming. Absolutely fascinating, and at the same time, truly terrifying information. Best regards, Jonathan
Thanks, I am glad you liked the video and thanks for the interest in the in-depth calculation by Peierls. This request got way more support than expected, which is fantastic. Anyway, I made the promised video, here it is: th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Very interesting especially about the "unknowns" in developing nuclear theory. And don't worry about the geneology slide. Pianists also want to brag about their lineage. My college piano instructor studied with someone who studied with someone who studied someone who studied with Liszt who studied with Czerny who studied with Beethoven! So there!
Up until that point they thought they would be so big that they would have to be delivered by boat, it must have been enlightening and somewhat terrifying to know the critical mass was much smaller than originally thought. Also there is a plaque on the University that shows that Frisch and Peierls first showed the feasibility of an airborne atomic weapon there
yeah, the mention of a bomb carried by boat shows the naive ideas about the size of the bomb. Some time ago I posted a picture of the plaque at U. of Birmingham th-cam.com/users/postUgkxeLp25z0xKqPBLU_rH9lhjILeDXEPcmuv
Excellent video. I am deeply impressed how clearly you explain the history of mathematical inventions that led to the construction of the bomb. Although mathematics is not my profession, you managed to convey how things work using "standard" words. What a wonderful show of professionalism. (often I see the opposite at TH-cam: using the most expensive words possible, using as much expensive words as possible to tell the a simple story not in one minute but in ten minutes)
Thanks for your kind message, I am glad you liked the video. The niche of this channel is a mix of historical context, some calculations, and use of original sources (original papers) and the viewers have actively asked me to include calculations instead of just superficial stories. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
@@jkzero Hi, as an elder hobbyist I am interested in "history behind history" - of course as far as it is a topic that has my interest. One example: I am interested in the history of airplanes. What role did an airplane play in history? Technical specifications are of minor interest to me. Take the Boeing B29 Superfortress for an example. It was the first airplane to deliver a nuclear bomb and thereby ending a world war. Next, it fell into the hands of the Sovjets who copied it and when the Russians built their own atom bomb, they had a copy of the B29 to deliver that bomb over American soil. This really gave the Americans a headache, because they had no interceptor to take their own design down. There are literally hundreds of these stories that make the history of aviation a joy to explore for me. So what impressed me about your video is "the history behind the history", the mathematical work that was done before construction of the bomb could even be started. I am really looking forward to other videos about this topic. And of course, the way you tell your story. As a former teacher, I concider it an art and a sign of mastership when somebody tells a story in the most comprehensible way.
@@retepeyahaled2961 thanks for sharing and congratulations on your continuous-learning attitude; I hope you enjoy the rest of the videos, I started with several on the physics of nuclear weapons and I am now running a video series on the origins of quantum mechanics. Thanks again for watching and welcome to the channel!
No worries that I am just getting started with the channel. Glad you liked it and that the mighty algorithm brought you here. Thanks for watching and welcome to the channel. Make sure to check the other videos.
Subscribed, didn't expect to learn anything new but I did. My old university is where Lise Meitner studied. Kinda sad there isn't any memorial. There is one for Boltzmann of course but she deserves one too and as an enthusiast of nuclear weapons design it is a bit cool that the place I studied was part of the story, even if only in a small way. BTW no silent letters in German, so it's appeoximately pronounced Lisey Meitner. Same as Porsche. Every letter is pronounced, German is a very consistent language, which I like. It's still horribly complicated though. A discussion of Krytrons or high voltage spark gap switches could be fun too, another piece of the puzzle. Today you can buy them but they only ship to the US :) I suppose modern bombs synchronise the detonators in a different way.
Thanks for watching and subscribing, that really helps the channel. I am glad that you found something new in the video, you are more than welcome to check out the other videos of the series. Thanks for the comment on the pronunciation of Lise Meitner's name, I struggle with it because I learned it as "Lisa" in my home country, then I moved to the US and I had to learn the American pronunciation, which stuck with me. You would be shocked by how the name of Karl Schwarzschild is pronounced in those others parts of the world. At least my students here in Germany were when I was teaching General Relativity and I said "Schwarzschild" out loud for the first time. You are so right, German is very consistent but also very hard, I have been for years in Germany and my German is still not even basic.
I am glad that you liked the video, I already see 4 votes for the solution of the neutron diffusion equation, I think it is a fantastic exercise for any student of differential equations. I will add it to my list of future videos.
As a nuclear engineering student, we were first introduced to calculating criticality using what was called the four-factor formula which had several terms relating to probabilities of fission, resonance escape, leakage etc.Then we moved on to the diffusion equation and the limitations of its assumptions. More exact answers are obtained using what is called neutron transport or monte carlo methods. I’d like to see the diffusion equation video. Another difficult concept to grasp is neutron kinetics, the time rate of change of neutron population in subcritical or supercritical systems and effects of delayed neutrons.
@@KevinBalch-dt8ot great to have someone with nuclear engineering expertise around, thanks for stopping by and welcome to the channel. You are right, early methods are quite crude, in fact Frisch and Peierls did several approximations, like ignoring the scattering cross-section, which significantly simplifies calculations because all the transport terms reduce to just fission terms. The four-factor formula is intended for reactor criticality but not for bomb criticality. In a bomb the goal is to let the neutron multiplication go wild as much as possible, contrary to the conditions in a reactor where you try control the neutron multiplication. Monte Carlo methods formally didn't exist when Peierls and Frisch did their calculations. Monte Carlo method was created during the development of thermonuclear bombs.
I’m a retired USAF Officer. I spent over 7 years underground with a 9 megaton Titan II ICBM. Upon a valid EWO Launch Message, I would have turned keys to launch this beast. I have a Bachelor’s degree in physics and electronics. You sir, and your physics are a big reason we speak English. Thank you.
Whoa, that's a hell of a CV you have there. I can't even imagine the levels of responsibility in such a job. I appreciate your nice comment. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
You are right, the Tube Alloy project was really what got the actual project for a bomb rolling, despite the simple narrative of Einstein-Szilard letter that most historical accounts prefer. I made a video about this, in case you what to check it out th-cam.com/video/W3ba1Y8L_yg/w-d-xo.html
One (minor) correction: It actually IS possible to enrich uranium with chemical methods because the different masses of the isotopes lead to some minute differences in reaction kinetics. France developed the CHEMEX process up to the pilot plant stage between 1968 and 1988, and Japan worked on a process based on ion exchange. Although none of them ultimately found any commercial usage. Another example (and one that is actually used commercially) of a chemical isotope separation process is the Girdler sulfide process which is the main way how heavy water (D2O) is produced today.
Hahn and Strassmann found short-lived radioactivity that could be percipitated from uranium salt solution using barium as carrier. That indicated that the trace-amount isotope was radium or barium, but since the active element could not be separated from barium via any chemical method, the implication was that this was in fact barium. Suported by findings of Curie-Savic team checked by Lise Meittner that the 3.5h half life isotope found in same uranium solution after neutron irradiation was lanthanum, Hahn and Strassman wereassured that neutron induced reaction in uranium is producing light elements contrary to Fermy's idea of transuranic elements. Few days after Hahn and Strassmann published their findings, Meittner understood that the atomic numbers of light elements produced are adding to 92 (atomic number of uranium) and after doing some liquid-drop model (model of nucleus developed by Neils Bohr) calculations she wrote back to Hahn and Strassman explaning that uranium nuclei were splitting producing light isotopes and about 200MeV of energy. Her nephew Otto Frish then improvised further experiments and in few days prooved this theory right, also giving the name to the reaction 'the fission' inspired by the name of cell-multiplying process (binary fission) in biology. In the next few months (in the spring od 1939) Joliot, Halban, Fermi, Frish and others found almost everything about uranium fission. That uranium 235 fissioned with low energy (thermal) neutrons, that uranium 238 fissioned with high energy neutrons, that the fission is producing 2 to 3 new, high energy neutrons...
The amount of barium produced indeed must have been fantastically small, I'd offhandedly guess a few nanograms at the absolute most, but maybe the video author can do some simple calculations to find the true range. The physical amount of Ba140 is immaterial though, since it has a tiny half-life of a dozen days it is screamingly radioactive and so all that is needed is to detect its radioactivity in a sample which was chemically obtained by a means previously known to isolate only barium. This method was a fractional recrystallization technique.
@@Muonium1 Ba140 yield in U235 fission is about 6%. Since Hahn and Strassmann were working with thermal neutrons only U235 fissioned, also, their sample was of natural uranium (first enriched uranium plant is still about 5yrs in future, the moment they discovered fission) total concentration of U235 was only about 0.72%. To know the real yield of Ba140 in mass one must know the burnup rate of uranium in their experiment, and that is extremly hard to calculate because very little original data are available. But to make educated guess, the burnup of uranium sample in Hahn and Strassmann experiment, I imagine, was in order of uWhr range. One Whr of burnup is 1.13x10^14 fissions. One uWhr burnup is 1.13x10^8 fissions. And that adds to ~6.75x10^6 Ba140 atoms per h. In one half life of Ba140 of burnup (13days od irradiation of uranium sample) there will be about 1.5x10^9 Ba140 atoms and that adds to about 50 p grams of Ba140. And the total produced Ba140 activity would be about 85kBq. That is more than enough activity to be measured nicely. As an ex nuke, the number feels about ok but, since I done the calculations in my head I'm almost sure I made mistake somewhere, so be free to check the numbers up. :D
the comments above provide a very complete picture. Yes, the amounts of Barium were small but very precise chemical measurements were possible and Hahn was recognized as the best radio-chemist of his time. If you want hard-core details, my suggestion is "The Making of the Atomic Bomb" by Richard Rhodes, it has a full chapter dedicated to the letters that Hahn wrote to Lise Meitner asking for her advice to understand his measurements. In the back and forth, it is possible to read how Hahn starts convinced that he observes "Radium-like Barium" but states that obviously it is not Barium (note that Radium is below Barium in the periodic table, so they share many chemical properties), to "it really looks like Barium but it cannot be Barium," but then goes into desperate mode to "we have done everything many times and we cannot separate it from Barium, please help" and finally to acceptance. He change the wording of his paper several times because he knew that he could ruin his reputation but he accepts that Barium is the only explanation. In the paper he even says that despite the report of Barium, some experimental error could be causing this "Barium fantasy."
@@glenliesegang233 It is impossible. Quantities of barium in experiments that lead to discovery of fission were so small that it is impossible to trace them via modern spectrometers. Even AAS spectrometer would struggle. They could be measured (and are) via gamma spectrocscopy but first usable gamma spectrometers were made during project Manhattan, and actually worked with conversion of gamma rays to photoelectrons and then measuring the energy spectra of those photoelectrons via magnetic sector speed separator, so to measure gamma spectra you would need really high activity of your sample. In conclusion, during 1930s only method of detecting trace amounts of radioelements was half-life measurement. And if You read papes by Curie, Fermi, Hahn, you will see that they used ONLY half life measurement for identifying. Please, do not write about something You clearely dont know a thing about... To be fair, percipitation methods of chemical microanalysis combined with half life measurements were quite sensitive qualitatively speaking as long as you had less than 3 radioistopes of the same element and as long as their half-lifes were quite different (about order of magnitude different).
This is really fascinating! I'm amazed they could determine these parameters with any degree of accuracy considering the crude equipment available then.
I am glad you liked it. I have always been fascinated by this story and, just like you said, all what they could do with so little tools available back then. In case you are interested, I posted a video with the full calculation that Peierls and Frisch did to calculate the critical mass here th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Gracias, me alegro te custara el video. En caso de que te interese, publiqué la derivación y solución de la ecuación de difusión de neutrones para calcular la masa crítica, como Peierls lo hizo originalmente th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
An complete and honestly the most embrancing, yet clear explanation about nuclear fisson qualitative machanics i've seen! Also... That part of neutron diffusion got my attention... It would be nice to have the proper video for it!
thanks fro the kind comment; I am glad that you found the video so valuable. I feel that I am making the videos that I wished I could have watched as a kid. The video walk-through solving the neutron diffusion equation has received way more support than expected, great to find more people interested in the stories but also in the calculations. It is in the pipeline, coming soon. I am curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
@@jkzero To be honest, the encounter with this video specificaly was made via recomendations! I don't have the most clean searching reference, as I usually research about scientific themes, but your playlist about nuclear physics poped up at the collum aside a video (specificaly, one from a non-scientifical topic), and so I was here! But, honestly, I find myself lucky for have been lead here... there's some serious work being done, and in a so good explanation, that I agree with fellow comments: there is less viwers/subscriptions than it should have
@@juliofaria4503 thanks for sharing and for the feedback, I appreciate the kind words of support. I hope to keep growing, I will keep making videos but in the end what keeps a channel alive is the interaction with viewers so thanks for commenting and sharing. I am glad that the mighty algorithm found you.
Dear Dr. Diaz, first of all many many thanks for your phenomenal video series in physics. Being a physicist myself I got highly interested in the history of physics in particular in the early history of quantum mechanics during the last several years. I can say with great conviction that your physics videos are absolutely outstanding ! Now to my question: Recently a perhaps very stupid idea came into my mind, when I listened to your depiction of the different ignition mechanisms of an atomic bomb, mainly the shot gun method used in little boy and the implosion method of trinity and fat man. Would it be possible to ignite an atomic bomb in the following way: Take a mass larger than the crital one (U-235 or Pu-239) and throttle down the exponentially increasing neutron flux by a neutron absorber, e.g. put a 'stick' of boron or cadmium right in the middle of the core. Of coarse It has to be dimensioned and shaped in a way that a chain reaction is safely suppressed. To ignite the bomb just remove the neutron absorber 'stick' as fast as possible, perhaps again by a shot gun method. The core would get hypercritcal and the bomb would ignite, in particular, if there is some extra neutron emitter (initiator) present in the core. I think the advantage compared to the conventional methods would be that the absorber (due to the low amount/mass of the absorber, how much of an absorber is needed ? I'm not able to do the math, at least not instantly.) can be ejected very rapidly from the core, at least much faster than two subcritical core masses can be shot into one another. With this isn't it possible even to properly ignite Pu-239, which otherwise would suffer from a too early explosion (fizzle) initiated by the Pu-240 rest in the mixture ? What do you think ? I mean the idea is just so simple that I can't imagine people didn't already have thought about it. Thanks again !
Glad you enjoyed it! There are many channels describing the general and qualitative aspects of nuclear physics but I thought that a more quantitative description was missing. I love solving equations and I have now found out that in addition to interesting stories many people really want to see calculations too for solving applied problems so I intend to fill that gap. Moreover, I wanted to tell the stories of less-known but crucial characters, like Frisch and Peierls in this video, and many others in future videos. Thanks for watching and welcome to the channel.
So this is something I have often wondered about. The basic model of fission is that neutrons fly out and split other atoms, but in order to get fission, you have to slow the neutrons down. This changes the whole idea does it not? It goes from a bullet hitting an target to one of a particle being attracted to and captured by the target atom.
the need of slowing down neutrons is only relevant for fissioning U-238 in a controlled manner, such as a nuclear reactor, this is the role of the moderator. Please check the follow-up video for Peierls & Frisch calculation of the heating and expansion of the nuclear core, which would stop the chain reaction. The process is so fast that slow neutrons cannot be used for a bomb; a bomb can only work with fast neutrons.
I find these stories fun and illuminating, they give a more human perspective. Textbooks present many ideas and, unless super famous, leave the protagonists aside. These stories, the people and the science, deserve to be shared
Feynman was very young, just graduated, when he joined the Manhattan Project. Still, he did more than just fixing calculation machines. I recommend this fantastic blog post by historian Alex Wellerstein titled "Feynman and the Bomb" blog.nuclearsecrecy.com/2014/06/06/feynman-and-the-bomb/
@@jkzero I based my comment on Feynman’s book. Maybe he was being modest about his contribution. Richard Rhodes “The Making of the Atomic Bomb” seems to confirm his relatively minor role. Considering these were all great scientists and mathematicians, even a “minor role” is not a slam. I’ve always been a huge Feynman fan.
Thanks, just in case you are interested, I also have now published a full video showing how to solve the neutron diffusion equation to determine the critical mass of an atomic bomb th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Hello! Great video. Small thing to 3:01 - uranium has 92 protons, 94 is plutonium, I bet you know this properly but some missnumbering happened :) Cheers!
oh nooooooooooooooo... the curse of copy+paste! How could this happen! Thank for notifying it, I really missed that. I try to be as careful as possible and for each video I watch the final version a dozen times looking for minor details but things still slip through. Yes, I know that uranium has 92 protons, this is a typo. Thanks again for watching with such attention.
Lise Meitner was ripped off by Otto Hann, as she was the one who interpreted the even as nuclear fission. He got all the credit. I digressed, this was an excellent presentation.
Lise Meitner is one of those terrible cases of neglect by the Nobel committee, she was nominated 19 times to the Nobel Prize in chemistry and 30 times to the Nobel Prize in physics.
She should have emigrated to the US or Britain. Unfortunately for her, she settled in Sweden - antisemitic and misogenistic at the time. She had no chances for the Nobel prize...
just to be nominated is a big deal. You are on the same level as the masters at that point and in in my eyes are of equal regard as one of the smartest people alive. Prost! Lise Meitner. 🎉
What must it have been like to arrive at these calculations -- in the end, simply arithmetical ones -- and to realize what in these numbers had been discovered and unleashed? I've occasionally been shocked by disappointing calculations concerning my checking-account balance, bad enough. But this?
Solving the diffusion equation is not trivial task, it requires calculus plus some clever approximations that go beyond the simple arithmetic manipulation shown in the video; however, it is something that any science or engineering undergrad could easily do. I can barely imagine how shocking and scary it must have been for Frisch and Peierls to find out that instead of tons of material only a few kilograms of U235 would be enough for a bomb; they probably checked and double-checked several times.
@@jkzeroYou're quite right, of course; I didn't mean to trivialize the calculation. But reliable approximations were soon within reach. There really is something spine-chilling about that image of the golf ball...
@@worldnotworldI loved that mention the "spine-chilling image of the golf ball" that was precisely what I wanted to transmit, that is how I felt it too. Even when I recorded the audio I said "2.1 cm... 2.1 cm!!!" twice in the voice of Doc Brown saying "1.21 GW" but I removed it because I sounded almost silly.
Thanks, I am glad you liked the video. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
@@jkzero it was the algorithm lol. i watch a lot of nuclear/radiation type videos and read a lot of articles on the stuff because it just truly fascinates me. Amazing how scientist figured all this stuff out with chemistry and math and no computers or internet....... I guess i shouldve gone to school to become a nuclear physicist....
I am pretty familiar with different nuke plant designs, know about most of the contaminated sites in the world, understand basic decay chains, radiation units, etc... wish there was some U mines near me
@@wyliesdiesels4169 Thanks for sharing and I am glad the algorithm is working, I hope you find the other videos of interest too and welcome to the channel. In case you haven't, make sure to check the series on quantum physics that I have been posting th-cam.com/play/PL_UV-wQj1lvVxch-RPQIUOHX88eeNGzVH.html
great that you liked it. The follow-up video is about Peierls and Frisch demonstrating that the nuclear chain reaction produces an explosion, check out the full playlist and let me know your impressions th-cam.com/play/PL_UV-wQj1lvUhNttvv4_KsYrQxHygj3Ey.html
Although it's considered that chemical separation of Uranium isotopes is not possible, there are in fact subtle timing differences in the rate of reaction between isotopes, which theoretically could be exploited.
Thanks, I am glad you liked the video and thanks for the interest in the in-depth calculation by Peierls. This request got way more support than expected in the comment, which is fantastic. Anyway, I published the promised video earlier this year, here it is: th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
thanks, I appreciate the appraisal; I do what I can with the narration but I take a long time and many iterations to complete a script so I am glad that it gets appreciated. Welcome to the channel.
You were wise to include the short summary about fission circa 1938 because that chapter as well as most everything else discussed in this video was either completely missing or, at best, poorly understood by the parts of my brain apportioned to understanding the development of science. Kudos to the TH-cam algorithm for bringing my attention to this video. Hamlet could well have been speaking directly to me, "There are more things in heaven and earth, Horatio, Than are dreamt of in your philosophy." I had an unfortunate aversion to math and science when I was in school which I am now determined to change. The story of atomic weapons, despite the unsettling reality of their use, is nevertheless a fascinating revelation of the world of the very small made discernable only by intricate mathematical equations and the application of logic and reason. It can also be seen as a spectacular success for the theory of science and the Calculus. What can be achieved by the greatest minds in physics teaming up for a common purpose is pretty amazing.
I am glad that the quick summary was useful, I wanted to go quickly over the story found in many other channels because I wanted to get to the part that most popular science channels or documentaries leave out. The story of nuclear physics and weapons is fascinating, despite, as you say, their unsettling reality. Every time watch footage of nuclear tests I can only think of them as terrifying beauty. Thanks for watching and welcome to the channel.
This video is a superb explanation of why the term “critical mass” is not quite correct. While I have only elementary physics knowledge, it’s clear from Dr. Diaz’s excellent narrative that other variables need to be considered, but particularly the density of the fissile material. How else could one produce an implosion bomb? It takes a sphere of plutonium and compresses it in order to initiate the explosion. If only mass were involved, since the mass of the plutonium did not change, comparing it before and after compression, it was the increased density of the material caused by sudden compression that was needed to initiate a sustainable chain reaction. Well done, Professor!
Thanks, I am glad you liked the video. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
Critical mass does not mean nuclear explosion! Criticality is the point at which a mass of a fissile material begins to start a chain reaction which leads to a huge increase in neutron flux, which is what killed the operator. How to initiate a nuclear explosion is another matter.
The rule of thumb for every tonne of uranium fissioned 8kg of plutonium is produced or put it the longer you cook uranium in a reactor the more plutonium. Plutonium is easily separated by chemical means the yellow uranium at the top and blue plutonium at the bottom. The spent uranium can be used in fast breeder reactors to produce further plutonium to extend fissile material. Enrichment of uranium is expensive and centrifuge technology is used and energy used is between 40kw and 110kw the Urenco TC21 centrifuge has a rotor length of 5m and 100 SWU per annum and AC100M centrifuge has a rotor length of 16.5m and is rated at 350 SWU . The SILEX process is new and the separative power index is unknown.
Thanks for subscribing! I am glad you found the content of interest, all the videos of this series in the playlist linked in the description above. Thanks for watching and welcome to the channel
Thanks, I am glad you liked the video. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
@@jkzero I've always been interested in physics. Particularly nuclear physics. I'm currently learning linear algebra and differential calc. It's a bit of a slog, but I'll keep working. I'm looking forward to watching the rest of your videos, and working the maths with you as I go. I really like how you incorporate formulae into your videos whenever possible
@@lahockeyboy Thanks for sharing and I am glad the algorithm is working, I hope you find the other videos of interest too and welcome to the channel. In case you want apply your differential-equations knowledge to the actual calculation of the critical mass, check my follow-up video th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Thanks, I am glad you liked it, make sure to check the rest of the playlist on the physics of nuclear weapons th-cam.com/play/PL_UV-wQj1lvUhNttvv4_KsYrQxHygj3Ey.html
Thanks for this video. I (a layman) am surprised to learn that so much info about the critical mass, essential to know if you want to create an atomic reaction/explosion =create military use of atomic physics, was in the open, i.e. published in scientific journals, for everyone to read, globally. One could have imagined that - when the enemy is listening in, there would have been a lot of censorship, hush-up etc. from authorities. But perhaps that came later (Los Alamos)?
All this information has been publicly available for decades. The details of these early weapons became quickly obsolete with the development of new kind of weapons. Moreover, knowing the physics is just a tiny part, converting that knowledge into a functioning device or getting access to the key materials is a whole another story.
I just discovered your videos, Congratulations and thanks for shearing your big knowledge your explanations are very clear.. there are a lot of super transcendental experiments but they are nor well explained like the oil droplet that you explained very clear and deep,etc. where can I find a list of your videos?
...thank you for this infomrative video. I've always thought of critical mass in terms of neutron flux and suprisingly Netron Diffusion Equation models just that. :D If neutron flux is not hight enough to reach criticality, just decrease fuels volume (cross section) so that the probability of neutrons to fission the atomic cores can increase. On the other hand if volume is constant, just increase fuels purity so the ratio of fissable and non fissable atomic cores is higher (relative cross section is higher)...
reaching criticality is tricky, but it can be done if we can find the relevant variables driving the criticality condition. cross-sections cannot be modified, they are fundamental properties of a material like uranium 235 or plutonium 239, but other properties can be controlled like the material density (critical mass is proportional to the inverse squared of the density) and enrichment ratio. The next video is a complete walk-through on how to solve the neutron diffusion equation to derive a general formula to calculate the critical mass in general of any pure fissile material so you might like that. It will be math heavy.
@@jkzero ..."relative cross section" was a rather choice of words on my side as cross-sections you are reffering in the video are fundamental properties. To me whole Neutron Diffusion Equation is like Bernoulli's Equation but instead of measuring fluid velocities and pressures we are measuring neutron flux and fissability. Either you change spatial dimension to increase flux or you increase density. Either ways it all comes down to how probbable is for a neutron and an atom to find themselves in a certain point of space and time for fission to occure. To me most amazing part in your video this time is historical aspect. In a matter of mere 5 years, someting that seemed theoretically impossible (a bomb) by Bohr's initail calculation for critical mass, was turned upside down and made possible (Trinity test)...:)
@@t850I see your point, in fact the derivation of the neutron diffusion equation involves properly describing the neutron density as a current, in my new video (in preparation) I even mention the similarity with fluids and electric currents.
@@jkzero ...in the end conservation of mass and energy holds true as all this equations are just a variation of this basic physical laws. I'm defenitely looking forward to seeing you new video...:)
@@t850 that is right, there is just a tiny but significant difference with neutrons diffusing inside a fissile material compared to an element of fluid or electric changes in a wire: the number of neutrons changes with time and position not only by diffusion but also because some neutrons are consumed by fission and new neutrons are created by fission so the continuity equation must be modified to include the corresponding source and sink terms.
I've often wondered whether criticality can be attained with less than the conventional "critical mass" of U-235. Could it be that a critical density is the true trigger for the reaction? In essence, what is the minimal mass requirement for initiating a nuclear fission chain reaction using U-235 or plutonium? I would greatly appreciate insightful responses. For those curious, my pondering was sparked by the first Predator movie. The scene where Arnold Schwarzenegger evades an explosion resembling a nuclear blast led me to consider this. However, it's implausible for him to have outrun an explosion comparable to the yield of "Little Boy" in such a brief span. Your input is valued. Thank you.
as described in the video, using modern values for density and fission cross-sections, the bare critical mass for pure U-235 is ~46 kg; however, you can push this down using a heavy metal around the uranium core called a tamper. The tamper helps in two ways: first, it reflects escaping neutrons back inside the core so they can produce more fission, and second, being heavy its inertia holds the exploding and expanding core for a few extra microseconds, which allows a few extra generations of neutron multiplication, and in an exponential growth the last few generations are the more crucial. How much you can push the critical mass down depends on the mass of the tamper, for instance, for a ~15 kg tamper the U-235 critical mass drops to ~30 kg, whereas for a 400 kg tamper the uranium core necessary for a bomb drops to ~18 kg.
@@nehorlavazapalka in my comment above, I was not referring to compression but only to the reduction of the necessary core mass by using a tamper surrounding the core
Excellent article. I do wonder however if Bohrs actually identified U235 as the key low speed neutron fissile material. Had he done so in any sort of public or published document the Manhatten project would have started in 1939. It did not start until 1942 because only then did Britain reveal the key document by Peierls and Frisch which definately identified U235 as the cirital isatope and they also predicted size of a critical mass and yield. This was the bomb. As you say a lot of people tried to claim credit that didn't deserve much; and I really don't believe Bohr knew about U235. If he did he kept his mouth shut and didn't reveal his knowlege until after the war. Which makes it irrellavent.
Bohr did identified U-235 as the key component of natural uranium responsible of the fission reactions with slow neutrons. He published two crucial papers in 1939, the first one alone in which he uses the differences between uranium and thorium as the key insight for the identification of U-235 titled "Resonance in Uranium and Thorium Disintegration and the Phenomenon of Nuclear Fission." The second paper, "Mechanism of Nuclear Fission," is the one mentioned at the 04:00 mark in the video. This paper co-authored with Wheeler shows all the gory calculations. Your comment about the British push to the bomb program is in fact the topic of the next video, stay tuned.
Thanks, I am glad you liked it. In case you are interested on the gory math details, I published a follow-up video showing step by step how to solve the equations to calculate the critical mass th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
When the Uranium is surrounded , enclosed by a diamond, the compressed matter starts to develop. Hundreds of electrons gather around it from the air, and the compressed matter from a single molecule will become the most dangerous one. The cosmic energy causes it to divide, but the diamond doesn't allow it. When it is not used up in time, one molecule explodes as a granade. When the molecule is fired at a tank or gets under a tank, the soldiers have to escape because of its high radioactivity, that's one molecule. The raioactivity is measured by an instrument to know when the matter has to be used up, or it will explode.
I guess their actions have to be analyzed in their historical context: they were really afraid that Heisenberg and his club of nuclear scientists would come similar conclusions
I know this is a simplistic view, but it's hard to believe some of the greatest scientific minds were procured for the purpose of blowing the enemy to hell.
I thought it was Leo Szilard who worked hard to convince scientists to hide their research, but most of the scientists being politically uninforned and focused on academic recognition were not easy to persuade. What was Leo Szilard' s role in the Manhatten Project? I feel he is another unrecognized hero. ♡ He did get ( through Einstein) King Leopold to send Belgium's stock of Pitchblend to the US. ♡ He did do his calculations to prove a chain reaction was possible. He filed a patent with British Admirality in 1933. ♡ He did convince Einstein to sign the letter to FDR. ♡ He did team up with Fermi in building the reactor at the Chicago Unvsity squash courts. ♡ Leslie Groves bought the patents to the zsilard / Fermi reactor for 10k.
thanks for your interest, the promised video explaining the details and solution of the neutron diffusion equation is already published, enjoy: th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Bought the Ophenhymer video but have no electricity to see it yet, well it,s always the nerd behind that really invented the bomb, It might seem possible to build a Americium 241 cigarette box bomb or a suit case bomb in accordance to enrichment.
The video walk-through solving the neutron diffusion equation has received way more support than expected, great to find more people interested in the stories but also in the calculations. It is in the pipeline, coming soon.
@@jkzero 20 years after graduation, I still remember my ODE's and modern physics. But I have never really applied it to a problem that was not given to me by a prof. I want to exercise that part of my brain again, and this is interesting. I remember we solved the Schrodinger eqn (ODE version) for Hydrogen. Then we used the matrix method, then we did a numerical estimation for Hydrogen. But that is the limit of my Modern Physics II course haha.
@@YoyomaG6 glad to read about your interest on challenging yourself intellectually, that is like taking the brain to the gym. The neutron diffusion equation is a PDE, not an ODE; however, don't get intimidated, after a little quite trivial trick the PDE can be turned into two ODEs and then all the methods that you know can be applied. As I said, this is coming soon with a "calculus warning" for anybody who might want to skip it due to high level. Still, it has been great finding an audience interested in the hard stuff.
Help please. I have trouble with the idea of compressing a solid. I understand the explosives compress a ball of plutonium to kick it over critical mass. Just how much does that ball of plutonium compress? I've seen it given as a solid ball. Somehow I'd expect a hollow ball to work, but I haven't seen anything on that. So, what's the deal? How much compression?
One more please; When testing the explosive lens, what did they use instead of the plutonium core AND did it remain compressed matter afterwards or return to its original size and shape?
@@DrJeffDrJeff wow, those a really good questions and I can safely say that I do not know the answers, I would have to do some digging. I cannot guarantee to be able to fulfill all the requests but I always open to collecting suggestions, thanks.
Thanks, in case you are interested, I also have a full video showing how to solve the neutron diffusion equation to determine the critical mass of an atomic bomb th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Thanks for your interest. I have already published a full video showing how to derive and solve the neutron diffusion equation to determine the critical mass of an atomic bomb here th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
_Comprehensive_ yet not *_abstruse!_* thanks so much p.s. Frequent misuse of the term "critical mass"? I found that distracting. Such as when, for example? So many social dynamics include this notion, along with _criticality_ and _tipping point._
I was referring to the non-technical use of the term "critical mass." In the corporate world is widely used as a way to say "all you need for something to happen is a critical mass" as having more people for a task is all that matters. I think this misses the point of the meaning of the borrowed term and also misses the opportunity to use it correctly: organizations want something to happen they need the minimum number of people but that is not enough, they also need the right conditions. This is the exact definition of criticality, not critical mass. In the original script and recording I had all this explained but during the editing this sounded more like a rant than a useful comment, cutting the flow of the video, so I took it out. Does this explanation make it more clear? Sorry that it got a bit long.
@@jkzeroYes, indeed. It caught my attention because I'm pre-occupied by how _"common usage"_ can distort discourse! So thanks for this: _" "all you need for something to happen is a critical mass"._ To be honest, I was trolling one particular sort of fish, so apologize if my question seemed cryptic and over-broad. Addendum? I read your _" they need the minimum number of people but that is not enough, they also need the right conditions"_ with great interest! An hour ago (quite literally!) I inserted the following into "notes to myself": _"What if there's an analogue of quantum mechanics in the domain of social cognition? What if, as light can be explored as wave and/or as particle, when observed one way a certain opinion seems perverse and illogical, while observed another way it seems antagonistic and oppositional? Then under the latter conditions, social transactions will most probably only amplify conflicts!"_ _thanks for your time!_ good of you /bdt
I think the "Fat Man" bomb casing was not a "Soccer Ball" A soccer ball is a "Truncated Icosahedron" It has 12 pentagons and 20 hexagons. In this object the "dihedral angels" are different at the intersection of the Pentagons and the Hexagons and the intersection of hexagon on hexagon. Where the pentagon is adjacent to a hexagon the dihedral angle is 142,62 degrees. Where the hexagon is adjacent to a hexagon the angle is 138.18 Secondly, the area of each polygon is different. Hence you would have different quantities of explosives arranged around the core at different angles. This also means the dihedral angle planes do not split the center of the objects circumscribing sphere. All in all this says that a soccer ball would not work. I think and I saw once a picture of the bombs casing. It was a "Deltoidal Hexecontahedron". This is an object with 60 kite shaped polygons. They form a sorta stellated dodecahedron. This would avoid the problems described above. I think the movie got it wrong. Let me know your thoughs.. Thanks, Hamp Stevens
wow, you really made me think deep here, thanks for that! I am not sure when/where in the video I said that the explosive lenses had the shape of a soccer ball, I used the soccer ball only as a reference of the size of a bare uranium core not the shape of the high explosives. Could you point out where this was inferred from in the video?
@@mkor7 honestly, I love pedantry, I can reach high levels of what you call being psychotically pedantic, although as a kid I learned (the wrong way) to keep it to myself
The video walk-through solving the neutron diffusion equation has received way more support than expected, great to find more people interested in the stories but also in the calculations. It is in the pipeline, coming soon.
Hahn and Strassmann guessed very well that they were getting Barium, but they have no explanation for it. At least the letters that Hahn wrote to Meitner show that he was in need of a physical explanation.
@@jkzero The very fact that in the letter he dismisses fission(although he doesn't use that word) as an explanation is proof enough that he had thought of it. I mean, if you make a discovery that conventional science says is impossible but it's staring you directly in the face, and you phone a friend who is the expert in the matter to consult her about what else could be going on, who made the discovery? You or the friend who reviewed your data? It actually drives me nuts because Hahn was actually doing good science in that he didn't seek to jump to a conclusion.
It would be interesting to know "how was it determined that Uranium 235 and Plutonium 240(?), we're the candidates for the bomb?". Why not lead? Potassium? Etc, etc" Also, what
several viewers have asked a similar question: out of all the elements of the periodic table, what makes Uranium 235 and Plutonium 239 special for the bomb? I will add this to my long list of videos in the pipeline, thanks for the suggestion. I am curious to know what brings viewers to the channel, were you searching for something in particular or the 'mighty algorithm' found you?
I am an electrical engineer with 40 years experience. For many years, I've been interested in the Manhattan story and certainly more interested after watching the movie Openhiemmer. Your critical mass video fascinating as you address questions that are in the realm of my grasp(barely)...and you explain who figured it out. It is amazing how those brilliant scientists used new understanding to invent the bomb(with it's horrific implications). Well, back to my questions. I've not seen any discussion "how was it discovered that Uranium and Plutonium were the candidates?". For example where there are number of research activities worldwide to analyze those elements within the periodic table for fissil properties? How is it known that fission will release large energy? How was it known, or speculated,, hydrogen fusion would release 1000(?) times more?
@@DESERTCB1 are you familiar with The Making of the Atomic Bomb by Richard Rhodes? there you find more details than expected, it is a terrific account of many things that most documentaries would not dare to get into. There is the story of how Leo Szilard proposes a series of experiments checking all the elements of the periodic table under neutron bombardment. In parallel, Fermi and his team in Rome did exactly that. Later with the famous Bohr-Wheeler paper, the search narrows down. I should definitely make a video about this in the future
@@DESERTCB1 oh the almighty algorithm, I am glad it has reached to so many people interested in these topics beyond the classic story but accompanied with some real calculations; I am very happy with the interest in the math and physics, in addition to the cool narratives
@@iAmDislikingEveryShort @amanthatthinks I was thinking of health effects. Having reread your comment I guess you were meaning experiments after that. Apologies, but equally interested. Anything history I find interesting and this is history about history. As an engineering student I'm interested in physics too, the Dr seems to have combined the two so the channel is extra interesting.
another vote for the solution of the neutron diffusion equation; I was honestly not expecting so many people asking for this so it is now in the to-do list. Coming soon so make sure to subscribe to get notified.
I hope this is a grade and not just a counter (sorry, I have been writing too much code lately); either way, thanks for watching and welcome to the channel
@jkzero Yes, but not even Otto Hahn understood what was happening. Furthermore, Fermi paved the way for conducting the experiment. In short, someone like Fermi can not be ignored. He, also, created the first nuclear reactor.
Thanks!
wow, thanks to you for supporting the channel! I really appreciate the gesture, for now I can only do my best to keep producing this kind of content. Thanks so much!
Chain reaction and critical mass was first discussed and patented (with A.Bomb) by Leo Szilard almost a decade before Hahn and Meitner and Strassmann.
@@chriswanger284 Thank you for that information. I wish we were building more nuclear power plants in the US. Wind Generators and Solar Panels are just such bullshit. Americans have been indoctrinated into Global Thermal/ CO2 thought extremes which are clearly lies. Anyway, thanks for your communications.
@@chriswanger284 you are correct on that; however, there is a big difference between chain reaction and fission. The former requires the later. Szilard's patent does not point to a specific element for the chain reaction. Szilard didn't know which element on the periodic table (in any) would sustain a nuclear chain reaction, he only patented a concept. Still relevant. In fact, his research program was bombarding one by one each element of the periodic table but Hahn and Strassmann tried uranium first and discovered nuclear fission. The actual verification of nuclear chain reaction was only possible at the Chicago Pile with Fermi, closely working with Szilard.
"I could talk about Peierls for hours....." please do! There is a large and appreciative audience for your content.....formal physics education is wasted on the young 🤭
Happy to see Peierls getting some love, and thanks for watching and the positive feedback.
@@jkzero Just want to second this - he’s one of the particular ones who doesn’t have anywhere near as well-known a story/contribution as the big Manhattan Project scientists.
British work beforehand on Maude/Tuballoys as well. And the Uranium Club and German institutions & scientists besides Heisenberg and his Bohr/Copenhagen peers.
I was just watching a Teller interview on web of stories where he was mentioning how he and Mitzi (maybe just her if he was testifying to Congress) got to go on a sightseeing trip to Mexico with the Peierls’ and Klaus Fuchs after the Manhattan Project was ended before Teller was to start his new position at the University of Chicago. Interesting collection of characters for a vacation.
I just discovered this channel I'm in love with the visuals along with your intuitive explanations. You easily deserve 100x your current following. Awesome videos
great that the algorithm someone brought you here; I am glad you found the content of interest and clearly explained. Thanks for the positive feedback. Just curious, what were you searching that brought you here? Thanks for watching and welcome to the channel.
@@jkzero I was initally reccomended the "Math of Saving the Enola Gay" video on the TH-cam homepage and decided to watch a few more of your videos. The algorithm knows all 😇
great to know that my first video is so much recommended by "the mighty algorithm" and thanks for exploring the rest of the channel. It is very quite new but quickly growing, which motivates me to keep making videos. Comments and suggestions for topics are more than welcome. I cannot guarantee to take all requests but I am collecting suggestions for the future, if there is any particular topic you are curious just let me know in the comments.
@@jkzero Ahh, I didn't realize that it was your first. Thats a high bar to set for yourself ;p. Something I am curious about is the calculations behind the arrangement of high and low speed explosives in an implosion style warhead. I've definitely heard it mentioned in several places but I don't remember the keywords to search for.
@@amelted thanks fro sharing your interests, I have watched dozens of documentaries and videos about the implosion design and I agree with you, the whole idea of how to turn the high-explosive's shockwaves inside-out for the implosion is always glanced over. I have a video about the implosion design in the pipeline because someone asked me "how much is the plutonium core compressed?" and I honestly had no idea. I did the calculation and I now know, so I plan a video for that, maybe I should create one about how the explosive lenses work. Thanks for the suggestion!
Thank you so much for this very interesting video on Dr. Peierls and fission. I've read some physics history and was already familiar with the great physicists of the 20th century; I've even got a poster of the famous photo of the Solvay conference on my office wall. I was unfamiliar with the work of Dr. Peierls and now can appreciate how important a physicist he was not only from a scientific viewpoint but a historical one as well. I look forward to further videos from you and perhaps you can write a book some day.
great to know that you got sir Rudolf Peierls (he was appointed a Commander of the Order of the British Empire) into your list of important physicists of the past century, like Hans Bethe, Peierls is a legend of physics, but unfortunately his importance requires lots of concepts to appreciate and for the same reason it is unlikely to have films about them. Thanks for watching and subscribe for more content coming.
A++ was a grade. Great presentation and well done.
appreciated, follow-up videos posted already so make sure to check them out
As a mechanical engineer, I was the only one to sign up for the full 2 courses in nuclear power at my small university. Fortunately, the professor allowed me to take the course as an independent study with the proviso that I do the reading and explain it before him. Never had I learned a subject so thoroughly.😂
Wow, that's a nice story; you have a point, when we attend lectures we expect the lecturer to do most of the work, if you are lecturing then that really forces you to prepare and learn. I am currently running a video series on the early times of quantum mechanics and I am using the original papers by Planck, Einstein, Bohr, etc, and I have learned a lot of content that doesn't make it to textbooks. Check it out, in case you haven't th-cam.com/play/PL_UV-wQj1lvVxch-RPQIUOHX88eeNGzVH.html
@@jkzeroThe textbooks always lack some important details I'm high school student but I prefer more original papers than textbook
I was at university studying physics and maths in the early 1960s.
I remember that one of our lecture courses was taught by Otto Frisch.
The topic of one of his lectures was the discovery of the electron.
He did not teach us about nuclear physics. That was done by somebody else.
Wow, that's a nice story, thanks for sharing. For what I read, Frisch kept a low profile after the war. Decades later he began sharing stories with his students about his life with Meitner, Bohr, and Stern. Only after retirement her daughter asked him to write those stories in a book. It was later publish as "What Little I Remember." I read it not long ago, it is a delight, I posted about it here th-cam.com/users/postUgkxtdfZmgblmHdpq2lY39GdI8IOGc92YmsT
A very good video, I gave a thumbs up and subscribed to the channel. Thank you for the great work. And yes, I'd love to see a video on the neutron diffusion equation.
Awesome, thank you! The video walk-through solving the neutron diffusion equation has received way more support than expected, great to find more people interested in the stories but also in the calculations. Thanks for watching and welcome to the channel
promise fulfilled: solving the neutron diffusion equation step by step th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Thank you Dr Diaz. I am so glad to have found your channel. I am thoroughly enjoying the fission bomb videos. Will you be doing any fusion bomb content at any point you think? (I don't mean right away, just at some point)
I am glad that you find the content of interest, there is plenty to talk about fission and some bomb physics, but fusion could also come in the future, requests are more than welcome so I will keep it in mind.
Good morning Dr. Diaz. I am now a subscriber to your superb channel. I came to it because I have had a life-long interest in nuclear physics relating to the development of atomic weapons. I have some physics background as part of my former career as a radiologist. The explanations you provide are amongst the clearest I have heard. I wish I could better understand some of the equations you display, but since I don’t intend to manufacture such devices, I’ll take that information “on faith.” Despite having thought I knew the basics of thermonuclear weapon design, I was surprised to learn that the major part of the “yield” is not simply a function of the amount of lithium deuteride, but the U238 casing around that material undergoing fission triggered by the fusion. I am still not clear if determination of the yield of the bomb also still depends on the amount of lithium deuteride, but hopefully that answer will be forthcoming. Absolutely fascinating, and at the same time, truly terrifying information. Best regards, Jonathan
Excellent work. Please, make a video about the derivation of the neutron diffusion equation as it was used by Peierls.
Thanks, I am glad you liked the video and thanks for the interest in the in-depth calculation by Peierls. This request got way more support than expected, which is fantastic. Anyway, I made the promised video, here it is: th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Very interesting especially about the "unknowns" in developing nuclear theory.
And don't worry about the geneology slide.
Pianists also want to brag about their lineage. My college piano instructor studied with someone who studied with someone who studied someone who studied with Liszt who studied with Czerny who studied with Beethoven! So there!
I would loooove a video on solving the neutron diffusion equation!
oh, it is done, enjoy: th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Up until that point they thought they would be so big that they would have to be delivered by boat, it must have been enlightening and somewhat terrifying to know the critical mass was much smaller than originally thought.
Also there is a plaque on the University that shows that Frisch and Peierls first showed the feasibility of an airborne atomic weapon there
yeah, the mention of a bomb carried by boat shows the naive ideas about the size of the bomb.
Some time ago I posted a picture of the plaque at U. of Birmingham th-cam.com/users/postUgkxeLp25z0xKqPBLU_rH9lhjILeDXEPcmuv
Excellent video. I am deeply impressed how clearly you explain the history of mathematical inventions that led to the construction of the bomb. Although mathematics is not my profession, you managed to convey how things work using "standard" words. What a wonderful show of professionalism. (often I see the opposite at TH-cam: using the most expensive words possible, using as much expensive words as possible to tell the a simple story not in one minute but in ten minutes)
Thanks for your kind message, I am glad you liked the video. The niche of this channel is a mix of historical context, some calculations, and use of original sources (original papers) and the viewers have actively asked me to include calculations instead of just superficial stories. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
@@jkzero Hi, as an elder hobbyist I am interested in "history behind history" - of course as far as it is a topic that has my interest. One example: I am interested in the history of airplanes. What role did an airplane play in history? Technical specifications are of minor interest to me. Take the Boeing B29 Superfortress for an example. It was the first airplane to deliver a nuclear bomb and thereby ending a world war. Next, it fell into the hands of the Sovjets who copied it and when the Russians built their own atom bomb, they had a copy of the B29 to deliver that bomb over American soil. This really gave the Americans a headache, because they had no interceptor to take their own design down. There are literally hundreds of these stories that make the history of aviation a joy to explore for me.
So what impressed me about your video is "the history behind the history", the mathematical work that was done before construction of the bomb could even be started. I am really looking forward to other videos about this topic. And of course, the way you tell your story. As a former teacher, I concider it an art and a sign of mastership when somebody tells a story in the most comprehensible way.
@@retepeyahaled2961 thanks for sharing and congratulations on your continuous-learning attitude; I hope you enjoy the rest of the videos, I started with several on the physics of nuclear weapons and I am now running a video series on the origins of quantum mechanics. Thanks again for watching and welcome to the channel!
My God, what an interesting great video! I am so sorry I didn't know about your youtube channel until now.
No worries that I am just getting started with the channel. Glad you liked it and that the mighty algorithm brought you here. Thanks for watching and welcome to the channel. Make sure to check the other videos.
Subscribed, didn't expect to learn anything new but I did. My old university is where Lise Meitner studied. Kinda sad there isn't any memorial. There is one for Boltzmann of course but she deserves one too and as an enthusiast of nuclear weapons design it is a bit cool that the place I studied was part of the story, even if only in a small way.
BTW no silent letters in German, so it's appeoximately pronounced Lisey Meitner. Same as Porsche. Every letter is pronounced, German is a very consistent language, which I like. It's still horribly complicated though.
A discussion of Krytrons or high voltage spark gap switches could be fun too, another piece of the puzzle. Today you can buy them but they only ship to the US :) I suppose modern bombs synchronise the detonators in a different way.
Thanks for watching and subscribing, that really helps the channel. I am glad that you found something new in the video, you are more than welcome to check out the other videos of the series.
Thanks for the comment on the pronunciation of Lise Meitner's name, I struggle with it because I learned it as "Lisa" in my home country, then I moved to the US and I had to learn the American pronunciation, which stuck with me. You would be shocked by how the name of Karl Schwarzschild is pronounced in those others parts of the world. At least my students here in Germany were when I was teaching General Relativity and I said "Schwarzschild" out loud for the first time. You are so right, German is very consistent but also very hard, I have been for years in Germany and my German is still not even basic.
I’ve never seen so many nuclear physicists on a YT page 😮
welcome to the channel
Another great video. Thanks for the upload!
Glad you enjoyed it! There is a follow-up video already posted
This video is so great 😍, I love it.
PS: Can you do the video about the neutron diffusion equation please😁, I would love to see that
I am glad that you liked the video, I already see 4 votes for the solution of the neutron diffusion equation, I think it is a fantastic exercise for any student of differential equations. I will add it to my list of future videos.
As a nuclear engineering student, we were first introduced to calculating criticality using what was called the four-factor formula which had several terms relating to probabilities of fission, resonance escape, leakage etc.Then we moved on to the diffusion equation and the limitations of its assumptions. More exact answers are obtained using what is called neutron transport or monte carlo methods.
I’d like to see the diffusion equation video. Another difficult concept to grasp is neutron kinetics, the time rate of change of neutron population in subcritical or supercritical systems and effects of delayed neutrons.
@@KevinBalch-dt8ot great to have someone with nuclear engineering expertise around, thanks for stopping by and welcome to the channel. You are right, early methods are quite crude, in fact Frisch and Peierls did several approximations, like ignoring the scattering cross-section, which significantly simplifies calculations because all the transport terms reduce to just fission terms. The four-factor formula is intended for reactor criticality but not for bomb criticality. In a bomb the goal is to let the neutron multiplication go wild as much as possible, contrary to the conditions in a reactor where you try control the neutron multiplication. Monte Carlo methods formally didn't exist when Peierls and Frisch did their calculations. Monte Carlo method was created during the development of thermonuclear bombs.
promise fulfilled: solving the neutron diffusion equation step by step th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
promise fulfilled: solving the neutron diffusion equation step by step th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
I’m a retired USAF Officer. I spent over 7 years underground with a 9 megaton Titan II ICBM. Upon a valid EWO Launch Message, I would have turned keys to launch this beast. I have a Bachelor’s degree in physics and electronics. You sir, and your physics are a big reason we speak English. Thank you.
Whoa, that's a hell of a CV you have there. I can't even imagine the levels of responsibility in such a job. I appreciate your nice comment. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
Do they really have those big floppy discs
The algorithm send me here, excelent content, new sub here!
@@jkzeroalgorithm
@@avo616 Thanks for sharing and I am glad the algorithm is working, I hope you find the other videos of interest too and welcome to the channel.
Tube alloy project was the start I read.
Tungsten Carbide blocks around the pit, Good neutron reflector.
You are right, the Tube Alloy project was really what got the actual project for a bomb rolling, despite the simple narrative of Einstein-Szilard letter that most historical accounts prefer. I made a video about this, in case you what to check it out th-cam.com/video/W3ba1Y8L_yg/w-d-xo.html
One (minor) correction: It actually IS possible to enrich uranium with chemical methods because the different masses of the isotopes lead to some minute differences in reaction kinetics. France developed the CHEMEX process up to the pilot plant stage between 1968 and 1988, and Japan worked on a process based on ion exchange. Although none of them ultimately found any commercial usage.
Another example (and one that is actually used commercially) of a chemical isotope separation process is the Girdler sulfide process which is the main way how heavy water (D2O) is produced today.
great video. How did they know they made Barium? It seems like the amount of Barium would be too small to detect.
Hahn and Strassmann found short-lived radioactivity that could be percipitated from uranium salt solution using barium as carrier. That indicated that the trace-amount isotope was radium or barium, but since the active element could not be separated from barium via any chemical method, the implication was that this was in fact barium. Suported by findings of Curie-Savic team checked by Lise Meittner that the 3.5h half life isotope found in same uranium solution after neutron irradiation was lanthanum, Hahn and Strassman wereassured that neutron induced reaction in uranium is producing light elements contrary to Fermy's idea of transuranic elements. Few days after Hahn and Strassmann published their findings, Meittner understood that the atomic numbers of light elements produced are adding to 92 (atomic number of uranium) and after doing some liquid-drop model (model of nucleus developed by Neils Bohr) calculations she wrote back to Hahn and Strassman explaning that uranium nuclei were splitting producing light isotopes and about 200MeV of energy. Her nephew Otto Frish then improvised further experiments and in few days prooved this theory right, also giving the name to the reaction 'the fission' inspired by the name of cell-multiplying process (binary fission) in biology. In the next few months (in the spring od 1939) Joliot, Halban, Fermi, Frish and others found almost everything about uranium fission. That uranium 235 fissioned with low energy (thermal) neutrons, that uranium 238 fissioned with high energy neutrons, that the fission is producing 2 to 3 new, high energy neutrons...
The amount of barium produced indeed must have been fantastically small, I'd offhandedly guess a few nanograms at the absolute most, but maybe the video author can do some simple calculations to find the true range. The physical amount of Ba140 is immaterial though, since it has a tiny half-life of a dozen days it is screamingly radioactive and so all that is needed is to detect its radioactivity in a sample which was chemically obtained by a means previously known to isolate only barium. This method was a fractional recrystallization technique.
@@Muonium1 Ba140 yield in U235 fission is about 6%. Since Hahn and Strassmann were working with thermal neutrons only U235 fissioned, also, their sample was of natural uranium (first enriched uranium plant is still about 5yrs in future, the moment they discovered fission) total concentration of U235 was only about 0.72%. To know the real yield of Ba140 in mass one must know the burnup rate of uranium in their experiment, and that is extremly hard to calculate because very little original data are available. But to make educated guess, the burnup of uranium sample in Hahn and Strassmann experiment, I imagine, was in order of uWhr range. One Whr of burnup is 1.13x10^14 fissions. One uWhr burnup is 1.13x10^8 fissions. And that adds to ~6.75x10^6 Ba140 atoms per h. In one half life of Ba140 of burnup (13days od irradiation of uranium sample) there will be about 1.5x10^9 Ba140 atoms and that adds to about 50 p grams of Ba140. And the total produced Ba140 activity would be about 85kBq. That is more than enough activity to be measured nicely. As an ex nuke, the number feels about ok but, since I done the calculations in my head I'm almost sure I made mistake somewhere, so be free to check the numbers up. :D
the comments above provide a very complete picture. Yes, the amounts of Barium were small but very precise chemical measurements were possible and Hahn was recognized as the best radio-chemist of his time. If you want hard-core details, my suggestion is "The Making of the Atomic Bomb" by Richard Rhodes, it has a full chapter dedicated to the letters that Hahn wrote to Lise Meitner asking for her advice to understand his measurements. In the back and forth, it is possible to read how Hahn starts convinced that he observes "Radium-like Barium" but states that obviously it is not Barium (note that Radium is below Barium in the periodic table, so they share many chemical properties), to "it really looks like Barium but it cannot be Barium," but then goes into desperate mode to "we have done everything many times and we cannot separate it from Barium, please help" and finally to acceptance. He change the wording of his paper several times because he knew that he could ruin his reputation but he accepts that Barium is the only explanation. In the paper he even says that despite the report of Barium, some experimental error could be causing this "Barium fantasy."
@@glenliesegang233 It is impossible. Quantities of barium in experiments that lead to discovery of fission were so small that it is impossible to trace them via modern spectrometers. Even AAS spectrometer would struggle. They could be measured (and are) via gamma spectrocscopy but first usable gamma spectrometers were made during project Manhattan, and actually worked with conversion of gamma rays to photoelectrons and then measuring the energy spectra of those photoelectrons via magnetic sector speed separator, so to measure gamma spectra you would need really high activity of your sample. In conclusion, during 1930s only method of detecting trace amounts of radioelements was half-life measurement. And if You read papes by Curie, Fermi, Hahn, you will see that they used ONLY half life measurement for identifying. Please, do not write about something You clearely dont know a thing about... To be fair, percipitation methods of chemical microanalysis combined with half life measurements were quite sensitive qualitatively speaking as long as you had less than 3 radioistopes of the same element and as long as their half-lifes were quite different (about order of magnitude different).
This is really fascinating!
I'm amazed they could determine these parameters with any degree of accuracy considering the crude equipment available then.
I am glad you liked it. I have always been fascinated by this story and, just like you said, all what they could do with so little tools available back then. In case you are interested, I posted a video with the full calculation that Peierls and Frisch did to calculate the critical mass here th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Great vídeo. Thank you so mucho for your explanations
Thanks for watching and welcome to the channel, there are already new videos and more coming soon. Subscription is highly appreciated ;)
Wonderful explanation of the history and science. Thanks.
Glad you liked it! Thanks for watching, for the support, and welcome to the channel.
Jorge, interesantisimo. Gracias por este regalito.
Gracias, me alegro te custara el video. En caso de que te interese, publiqué la derivación y solución de la ecuación de difusión de neutrones para calcular la masa crítica, como Peierls lo hizo originalmente th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
An complete and honestly the most embrancing, yet clear explanation about nuclear fisson qualitative machanics i've seen! Also... That part of neutron diffusion got my attention... It would be nice to have the proper video for it!
thanks fro the kind comment; I am glad that you found the video so valuable. I feel that I am making the videos that I wished I could have watched as a kid. The video walk-through solving the neutron diffusion equation has received way more support than expected, great to find more people interested in the stories but also in the calculations. It is in the pipeline, coming soon. I am curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
@@jkzero To be honest, the encounter with this video specificaly was made via recomendations! I don't have the most clean searching reference, as I usually research about scientific themes, but your playlist about nuclear physics poped up at the collum aside a video (specificaly, one from a non-scientifical topic), and so I was here! But, honestly, I find myself lucky for have been lead here... there's some serious work being done, and in a so good explanation, that I agree with fellow comments: there is less viwers/subscriptions than it should have
@@juliofaria4503 thanks for sharing and for the feedback, I appreciate the kind words of support. I hope to keep growing, I will keep making videos but in the end what keeps a channel alive is the interaction with viewers so thanks for commenting and sharing. I am glad that the mighty algorithm found you.
promise fulfilled: solving the neutron diffusion equation step by step th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Dear Dr. Diaz, first of all many many thanks for your phenomenal video series in physics. Being a physicist myself I got highly interested in the history of physics in particular in the early history of quantum mechanics during the last several years. I can say with great conviction that your physics videos are absolutely outstanding !
Now to my question: Recently a perhaps very stupid idea came into my mind, when I listened to your depiction of the different ignition mechanisms of an atomic bomb, mainly the shot gun method used in little boy and the implosion method of trinity and fat man. Would it be possible to ignite an atomic bomb in the following way: Take a mass larger than the crital one (U-235 or Pu-239) and throttle down the exponentially increasing neutron flux by a neutron absorber, e.g. put a 'stick' of boron or cadmium right in the middle of the core. Of coarse It has to be dimensioned and shaped in a way that a chain reaction is safely suppressed. To ignite the bomb just remove the neutron absorber 'stick' as fast as possible, perhaps again by a shot gun method. The core would get hypercritcal and the bomb would ignite, in particular, if there is some extra neutron emitter (initiator) present in the core. I think the advantage compared to the conventional methods would be that the absorber (due to the low amount/mass of the absorber, how much of an absorber is needed ? I'm not able to do the math, at least not instantly.) can be ejected very rapidly from the core, at least much faster than two subcritical core masses can be shot into one another. With this isn't it possible even to properly ignite Pu-239, which otherwise would suffer from a too early explosion (fizzle) initiated by the Pu-240 rest in the mixture ? What do you think ? I mean the idea is just so simple that I can't imagine people didn't already have thought about it. Thanks again !
Great video - thsnk you! It fills in some gaps that some of us want to know.
Glad you enjoyed it! There are many channels describing the general and qualitative aspects of nuclear physics but I thought that a more quantitative description was missing. I love solving equations and I have now found out that in addition to interesting stories many people really want to see calculations too for solving applied problems so I intend to fill that gap. Moreover, I wanted to tell the stories of less-known but crucial characters, like Frisch and Peierls in this video, and many others in future videos. Thanks for watching and welcome to the channel.
So this is something I have often wondered about. The basic model of fission is that neutrons fly out and split other atoms, but in order to get fission, you have to slow the neutrons down. This changes the whole idea does it not? It goes from a bullet hitting an target to one of a particle being attracted to and captured by the target atom.
the need of slowing down neutrons is only relevant for fissioning U-238 in a controlled manner, such as a nuclear reactor, this is the role of the moderator. Please check the follow-up video for Peierls & Frisch calculation of the heating and expansion of the nuclear core, which would stop the chain reaction. The process is so fast that slow neutrons cannot be used for a bomb; a bomb can only work with fast neutrons.
Thanks to this video, I finally learned how to calculate critical mass.
excellent! Now use this knowledge wisely :)
@@jkzero You don't have to worry.
Pretty cool how bits of history are intertwined with the physics
I find these stories fun and illuminating, they give a more human perspective. Textbooks present many ideas and, unless super famous, leave the protagonists aside. These stories, the people and the science, deserve to be shared
Wonderful video!! Thank you so much!
Thank you too for watching and leaving a comment. The latest video in the channel is about what came next, so check it out!
@@jkzero oooo, I certainly will! Thanks!😁
Great video! At 3:00 it's supposed to be 92 protons + 143 neutrons and 92 protons + 146 neutrons for u235 and u238, respectively.
yes, you are right, I totally messed that up; good catch. I added the erratum in the video description.
I know Feynman worked on the project, but as I recall, he played a minor part fixing the calculation machines
Feynman was very young, just graduated, when he joined the Manhattan Project. Still, he did more than just fixing calculation machines. I recommend this fantastic blog post by historian Alex Wellerstein titled "Feynman and the Bomb" blog.nuclearsecrecy.com/2014/06/06/feynman-and-the-bomb/
@@jkzero I based my comment on Feynman’s book. Maybe he was being modest about his contribution. Richard Rhodes “The Making of the Atomic Bomb” seems to confirm his relatively minor role. Considering these were all great scientists and mathematicians, even a “minor role” is not a slam. I’ve always been a huge Feynman fan.
This video provided great information and a great history lesson. Thanks!
Thanks, just in case you are interested, I also have now published a full video showing how to solve the neutron diffusion equation to determine the critical mass of an atomic bomb th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Hello! Great video. Small thing to 3:01 - uranium has 92 protons, 94 is plutonium, I bet you know this properly but some missnumbering happened :) Cheers!
oh nooooooooooooooo... the curse of copy+paste! How could this happen! Thank for notifying it, I really missed that. I try to be as careful as possible and for each video I watch the final version a dozen times looking for minor details but things still slip through. Yes, I know that uranium has 92 protons, this is a typo. Thanks again for watching with such attention.
Lise Meitner was ripped off by Otto Hann, as she was the one who interpreted the even as nuclear fission. He got all the credit. I digressed, this was an excellent presentation.
Lise Meitner is one of those terrible cases of neglect by the Nobel committee, she was nominated 19 times to the Nobel Prize in chemistry and 30 times to the Nobel Prize in physics.
She should have emigrated to the US or Britain. Unfortunately for her, she settled in Sweden - antisemitic and misogenistic at the time. She had no chances for the Nobel prize...
just to be nominated is a big deal. You are on the same level as the masters at that point and in in my eyes are of equal regard as one of the smartest people alive. Prost! Lise Meitner. 🎉
Thankfully they named an element after her, after they discovered this.
Thanks for making and sharing this video. And yes, I'd appreciate a video on the neutron diffusion equation.
I am glad you liked the video and the video solving the neutron diffusion equation is now published, check the most recent video on the channel
@@jkzero Thanks. Just a suggestion, you might want to add a note to this video about the neutron diffusion equation being publishes.
@@rmandra good suggestion, thanks! And done!
12:17: Me: "Holy (insert crude word!)". Extremely interesting discussion.
totally agree: that must have been a holy s**t moment for the German and Austrian, knowing that Heisenberg could easily calculate this too
an excellent video. i think the pacing is perfect.
I am glad you found the content of interest, make sure to check the several new videos. Thanks for watching and welcome to the channel.
Excellent video
Thanks for watching and welcome to the channel, there are already new videos and more coming soon. Subscription is highly appreciated ;)
What must it have been like to arrive at these calculations -- in the end, simply arithmetical ones -- and to realize what in these numbers had been discovered and unleashed? I've occasionally been shocked by disappointing calculations concerning my checking-account balance, bad enough. But this?
Solving the diffusion equation is not trivial task, it requires calculus plus some clever approximations that go beyond the simple arithmetic manipulation shown in the video; however, it is something that any science or engineering undergrad could easily do. I can barely imagine how shocking and scary it must have been for Frisch and Peierls to find out that instead of tons of material only a few kilograms of U235 would be enough for a bomb; they probably checked and double-checked several times.
@@jkzeroYou're quite right, of course; I didn't mean to trivialize the calculation. But reliable approximations were soon within reach. There really is something spine-chilling about that image of the golf ball...
@@worldnotworld I am pretty sure that Frisch and Peierls got a shiver when they got R_c = 2.1 cm
@@worldnotworldI loved that mention the "spine-chilling image of the golf ball" that was precisely what I wanted to transmit, that is how I felt it too. Even when I recorded the audio I said "2.1 cm... 2.1 cm!!!" twice in the voice of Doc Brown saying "1.21 GW" but I removed it because I sounded almost silly.
@@jkzero You did just the right thing by not playing up the melodrama _at all._ It makes the image even more striking, really.
i just love history and i love learning about nuclear physics and the history of the bomb.... fascinating stuff. thanks for the videos...
Thanks, I am glad you liked the video. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
@@jkzero it was the algorithm lol. i watch a lot of nuclear/radiation type videos and read a lot of articles on the stuff because it just truly fascinates me. Amazing how scientist figured all this stuff out with chemistry and math and no computers or internet....... I guess i shouldve gone to school to become a nuclear physicist....
I am pretty familiar with different nuke plant designs, know about most of the contaminated sites in the world, understand basic decay chains, radiation units, etc... wish there was some U mines near me
@@wyliesdiesels4169 Thanks for sharing and I am glad the algorithm is working, I hope you find the other videos of interest too and welcome to the channel. In case you haven't, make sure to check the series on quantum physics that I have been posting th-cam.com/play/PL_UV-wQj1lvVxch-RPQIUOHX88eeNGzVH.html
Dang. Facinating. Tell me that you are going to do a follow up video.
great that you liked it. The follow-up video is about Peierls and Frisch demonstrating that the nuclear chain reaction produces an explosion, check out the full playlist and let me know your impressions th-cam.com/play/PL_UV-wQj1lvUhNttvv4_KsYrQxHygj3Ey.html
Although it's considered that chemical separation of Uranium isotopes is not possible, there are in fact subtle timing differences in the rate of reaction between isotopes, which theoretically could be exploited.
That's interesting; I wonder of these reactions affect the recollection of each isotope rendering useless in any way.
An excellent and descriptive video.
Many thanks! The follow-up video is already posted, enjoy.
Awesome informative!
Please talk about Rudolf Peierls for hours! 👍😃
And yes I would also like to learn more about the Neutron Diffusion Equation!😉
Thanks, I am glad you liked the video and thanks for the interest in the in-depth calculation by Peierls. This request got way more support than expected in the comment, which is fantastic. Anyway, I published the promised video earlier this year, here it is: th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
You are a great story teller!
thanks, I appreciate the appraisal; I do what I can with the narration but I take a long time and many iterations to complete a script so I am glad that it gets appreciated. Welcome to the channel.
You were wise to include the short summary about fission circa 1938 because that chapter as well as most everything else discussed in this video was either completely missing or, at best, poorly understood by the parts of my brain apportioned to understanding the development of science. Kudos to the TH-cam algorithm for bringing my attention to this video. Hamlet could well have been speaking directly to me,
"There are more things in heaven and earth, Horatio,
Than are dreamt of in your philosophy."
I had an unfortunate aversion to math and science when I was in school which I am now determined to change. The story of atomic weapons, despite the unsettling reality of their use, is nevertheless a fascinating revelation of the world of the very small made discernable only by intricate mathematical equations and the application of logic and reason. It can also be seen as a spectacular success for the theory of science and the Calculus. What can be achieved by the greatest minds in physics teaming up for a common purpose is pretty amazing.
I am glad that the quick summary was useful, I wanted to go quickly over the story found in many other channels because I wanted to get to the part that most popular science channels or documentaries leave out. The story of nuclear physics and weapons is fascinating, despite, as you say, their unsettling reality. Every time watch footage of nuclear tests I can only think of them as terrifying beauty. Thanks for watching and welcome to the channel.
This video is a superb explanation of why the term “critical mass” is not quite correct. While I have only elementary physics knowledge, it’s clear from Dr. Diaz’s excellent narrative that other variables need to be considered, but particularly the density of the fissile material. How else could one produce an implosion bomb? It takes a sphere of plutonium and compresses it in order to initiate the explosion. If only mass were involved, since the mass of the plutonium did not change, comparing it before and after compression, it was the increased density of the material caused by sudden compression that was needed to initiate a sustainable chain reaction. Well done, Professor!
Thanks, I am glad you liked the video. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
Critical mass does not mean nuclear explosion! Criticality is the point at which a mass of a fissile material begins to start a chain reaction which leads to a huge increase in neutron flux, which is what killed the operator. How to initiate a nuclear explosion is another matter.
The rule of thumb for every tonne of uranium fissioned 8kg of plutonium is produced or put it the longer you cook uranium in a reactor the more plutonium. Plutonium is easily separated by chemical means the yellow uranium at the top and blue plutonium at the bottom. The spent uranium can be used in fast breeder reactors to produce further plutonium to extend fissile material. Enrichment of uranium is expensive and centrifuge technology is used and energy used is between 40kw and 110kw the Urenco TC21 centrifuge has a rotor length of 5m and 100 SWU per annum and AC100M centrifuge has a rotor length of 16.5m and is rated at 350 SWU . The SILEX process is new and the separative power index is unknown.
SILEX: About 10-20% enrichment per pass.
Prolonged irradiation in the reactor poisons Pu with by-products. So there is a balance
Wow, what a great video, subscribed! Now to watch your others 🙂
Thanks for subscribing! I am glad you found the content of interest, all the videos of this series in the playlist linked in the description above. Thanks for watching and welcome to the channel
Great videos, Professor! Muchos Gracias
Thanks, I am glad you liked the video. I am always curious to know what brings viewers to the channel, were you searching for something in particular or did the 'mighty algorithm' find you?
@@jkzero I've always been interested in physics. Particularly nuclear physics. I'm currently learning linear algebra and differential calc. It's a bit of a slog, but I'll keep working. I'm looking forward to watching the rest of your videos, and working the maths with you as I go. I really like how you incorporate formulae into your videos whenever possible
@@lahockeyboy Thanks for sharing and I am glad the algorithm is working, I hope you find the other videos of interest too and welcome to the channel. In case you want apply your differential-equations knowledge to the actual calculation of the critical mass, check my follow-up video th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
@@jkzero thanks, professor!
great video thank you
Thanks, I am glad you liked it, make sure to check the rest of the playlist on the physics of nuclear weapons th-cam.com/play/PL_UV-wQj1lvUhNttvv4_KsYrQxHygj3Ey.html
@@jkzero sure will
An excellent presentation.
Thanks, I am glad you liked the video.
🙏🙏🙏🙏🙏 love it…., I understand just enough to hold the edge of the conversation and imagine our Quantum world 🙏🙏🙏
Clever people eh
Thanks for this video.
I (a layman) am surprised to learn that so much info about the critical mass, essential to know if you want to create an atomic reaction/explosion =create military use of atomic physics, was in the open, i.e. published in scientific journals, for everyone to read, globally. One could have imagined that - when the enemy is listening in, there would have been a lot of censorship, hush-up etc. from authorities. But perhaps that came later (Los Alamos)?
All this information has been publicly available for decades. The details of these early weapons became quickly obsolete with the development of new kind of weapons. Moreover, knowing the physics is just a tiny part, converting that knowledge into a functioning device or getting access to the key materials is a whole another story.
Very interesting
I just discovered your videos, Congratulations and thanks for shearing your big knowledge your explanations are very clear.. there are a lot of super transcendental experiments but they are nor well explained like the oil droplet that you explained very clear and deep,etc. where can I find a list of your videos?
Thanks for watching and welcome to the channel. You can find a list with all the videos here: www.youtube.com/@jkzero/videos
Please upload a vid where you talk about Peierls for hours. Thnx!
that is an interesting challenge
@@jkzero tape begins to turn ....
Incredible lecture
Thanks, I am glad you liked it, make sure to check the rest of the playlist on the physics of nuclear weapons.
Very good video !
Merci
Glad you liked it! Thanks to you for watching and welcome to the channel
...thank you for this infomrative video. I've always thought of critical mass in terms of neutron flux and suprisingly Netron Diffusion Equation models just that. :D
If neutron flux is not hight enough to reach criticality, just decrease fuels volume (cross section) so that the probability of neutrons to fission the atomic cores can increase. On the other hand if volume is constant, just increase fuels purity so the ratio of fissable and non fissable atomic cores is higher (relative cross section is higher)...
reaching criticality is tricky, but it can be done if we can find the relevant variables driving the criticality condition. cross-sections cannot be modified, they are fundamental properties of a material like uranium 235 or plutonium 239, but other properties can be controlled like the material density (critical mass is proportional to the inverse squared of the density) and enrichment ratio. The next video is a complete walk-through on how to solve the neutron diffusion equation to derive a general formula to calculate the critical mass in general of any pure fissile material so you might like that. It will be math heavy.
@@jkzero ..."relative cross section" was a rather choice of words on my side as cross-sections you are reffering in the video are fundamental properties.
To me whole Neutron Diffusion Equation is like Bernoulli's Equation but instead of measuring fluid velocities and pressures we are measuring neutron flux and fissability. Either you change spatial dimension to increase flux or you increase density. Either ways it all comes down to how probbable is for a neutron and an atom to find themselves in a certain point of space and time for fission to occure.
To me most amazing part in your video this time is historical aspect. In a matter of mere 5 years, someting that seemed theoretically impossible (a bomb) by Bohr's initail calculation for critical mass, was turned upside down and made possible (Trinity test)...:)
@@t850I see your point, in fact the derivation of the neutron diffusion equation involves properly describing the neutron density as a current, in my new video (in preparation) I even mention the similarity with fluids and electric currents.
@@jkzero ...in the end conservation of mass and energy holds true as all this equations are just a variation of this basic physical laws.
I'm defenitely looking forward to seeing you new video...:)
@@t850 that is right, there is just a tiny but significant difference with neutrons diffusing inside a fissile material compared to an element of fluid or electric changes in a wire: the number of neutrons changes with time and position not only by diffusion but also because some neutrons are consumed by fission and new neutrons are created by fission so the continuity equation must be modified to include the corresponding source and sink terms.
I've often wondered whether criticality can be attained with less than the conventional "critical mass" of U-235. Could it be that a critical density is the true trigger for the reaction?
In essence, what is the minimal mass requirement for initiating a nuclear fission chain reaction using U-235 or plutonium? I would greatly appreciate insightful responses.
For those curious, my pondering was sparked by the first Predator movie. The scene where Arnold Schwarzenegger evades an explosion resembling a nuclear blast led me to consider this. However, it's implausible for him to have outrun an explosion comparable to the yield of "Little Boy" in such a brief span. Your input is valued. Thank you.
as described in the video, using modern values for density and fission cross-sections, the bare critical mass for pure U-235 is ~46 kg; however, you can push this down using a heavy metal around the uranium core called a tamper. The tamper helps in two ways: first, it reflects escaping neutrons back inside the core so they can produce more fission, and second, being heavy its inertia holds the exploding and expanding core for a few extra microseconds, which allows a few extra generations of neutron multiplication, and in an exponential growth the last few generations are the more crucial. How much you can push the critical mass down depends on the mass of the tamper, for instance, for a ~15 kg tamper the U-235 critical mass drops to ~30 kg, whereas for a 400 kg tamper the uranium core necessary for a bomb drops to ~18 kg.
@@jkzero As far as I understand, pure uranium has bad compressibility in a solid core, so probably very hard to do
@@nehorlavazapalka in my comment above, I was not referring to compression but only to the reduction of the necessary core mass by using a tamper surrounding the core
Excellent article. I do wonder however if Bohrs actually identified U235 as the key low speed neutron fissile material. Had he done so in any sort of public or published document the Manhatten project would have started in 1939. It did not start until 1942 because only then did Britain reveal the key document by Peierls and Frisch which definately identified U235 as the cirital isatope and they also predicted size of a critical mass and yield. This was the bomb. As you say a lot of people tried to claim credit that didn't deserve much; and I really don't believe Bohr knew about U235. If he did he kept his mouth shut and didn't reveal his knowlege until after the war.
Which makes it irrellavent.
Bohr did identified U-235 as the key component of natural uranium responsible of the fission reactions with slow neutrons. He published two crucial papers in 1939, the first one alone in which he uses the differences between uranium and thorium as the key insight for the identification of U-235 titled "Resonance in Uranium and Thorium Disintegration and the Phenomenon of Nuclear Fission." The second paper, "Mechanism of Nuclear Fission," is the one mentioned at the 04:00 mark in the video. This paper co-authored with Wheeler shows all the gory calculations. Your comment about the British push to the bomb program is in fact the topic of the next video, stay tuned.
It's late. As the history unfolded I dozed off. Luckily, I woke up just in time for the critical mass calculation. (I will watch this again).
Great video
Thanks, I am glad you liked it. In case you are interested on the gory math details, I published a follow-up video showing step by step how to solve the equations to calculate the critical mass th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
When the Uranium is surrounded , enclosed by a diamond, the compressed matter starts to develop. Hundreds of electrons gather around it from the air, and the compressed matter from a single molecule will become the most dangerous one. The cosmic energy causes it to divide, but the diamond doesn't allow it. When it is not used up in time, one molecule explodes as a granade. When the molecule is fired at a tank or gets under a tank, the soldiers have to escape because of its high radioactivity, that's one molecule.
The raioactivity is measured by an instrument to know when the matter has to be used up, or it will explode.
I am sorry but I have no idea you are describing
great video
Excellent video, too bad I need new glasses so a lot of it was blurry.
So you woulda thunk that the first scientists splitting the atom and realizing it could be turned into a bomb might have just kept that to themselves.
I guess their actions have to be analyzed in their historical context: they were really afraid that Heisenberg and his club of nuclear scientists would come similar conclusions
I know this is a simplistic view, but it's hard to believe some of the greatest scientific minds were procured for the purpose of blowing the enemy to hell.
I understand and share the feeling, but at the same time I imagine that given the threat their action were in fact survival
I thought it was Leo Szilard who worked hard to convince scientists to hide their research, but most of the scientists being politically uninforned and focused on academic recognition were not easy to persuade.
What was Leo Szilard' s role in the Manhatten Project?
I feel he is another unrecognized hero.
♡ He did get ( through Einstein) King Leopold to send Belgium's stock of Pitchblend to the US.
♡ He did do his calculations to prove a chain reaction was possible. He filed a patent with British Admirality in 1933.
♡ He did convince Einstein to sign the letter to FDR.
♡ He did team up with Fermi in building the reactor at the Chicago Unvsity squash courts.
♡ Leslie Groves bought the patents to the zsilard / Fermi reactor for 10k.
Is it still secret exactly what was the initiator was in the plutonium bomb that added a burst of neutrons ?
Sandia makes a nice tritium micro-triĝger, I figure this is what your talking about.
Pls, explain the diffusion theory and neutron diffusion equation
thanks for your interest, the promised video explaining the details and solution of the neutron diffusion equation is already published, enjoy: th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Bought the Ophenhymer video but have no electricity to see it yet, well it,s always the nerd behind that really invented the bomb, It might seem possible to build a Americium 241 cigarette box bomb or a suit case bomb in accordance to enrichment.
Awesome video. After 3 ODE classes i still dont have a real application beyond the springs on springs in a triangle pattern. Please, the derivation!
The video walk-through solving the neutron diffusion equation has received way more support than expected, great to find more people interested in the stories but also in the calculations. It is in the pipeline, coming soon.
@@jkzero 20 years after graduation, I still remember my ODE's and modern physics. But I have never really applied it to a problem that was not given to me by a prof. I want to exercise that part of my brain again, and this is interesting. I remember we solved the Schrodinger eqn (ODE version) for Hydrogen. Then we used the matrix method, then we did a numerical estimation for Hydrogen. But that is the limit of my Modern Physics II course haha.
@@YoyomaG6 glad to read about your interest on challenging yourself intellectually, that is like taking the brain to the gym. The neutron diffusion equation is a PDE, not an ODE; however, don't get intimidated, after a little quite trivial trick the PDE can be turned into two ODEs and then all the methods that you know can be applied. As I said, this is coming soon with a "calculus warning" for anybody who might want to skip it due to high level. Still, it has been great finding an audience interested in the hard stuff.
promise fulfilled: solving the neutron diffusion equation step by step th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Help please. I have trouble with the idea of compressing a solid. I understand the explosives compress a ball of plutonium to kick it over critical mass. Just how much does that ball of plutonium compress? I've seen it given as a solid ball. Somehow I'd expect a hollow ball to work, but I haven't seen anything on that. So, what's the deal? How much compression?
I made a video answering this exact question, check at the 3:28 mark of this video th-cam.com/video/AcwZ0cwxXOE/w-d-xo.html
@@jkzero Wow. Thank you.
One more please; When testing the explosive lens, what did they use instead of the plutonium core AND did it remain compressed matter afterwards or return to its original size and shape?
@@DrJeffDrJeff wow, those a really good questions and I can safely say that I do not know the answers, I would have to do some digging. I cannot guarantee to be able to fulfill all the requests but I always open to collecting suggestions, thanks.
AMAZING VIDEO ❤️❤️❤️❤️❤️❤️❤️
Thanks, in case you are interested, I also have a full video showing how to solve the neutron diffusion equation to determine the critical mass of an atomic bomb th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Dear doctor! Can you derive the differential equation you showed from first principles please?
Thanks for your interest. I have already published a full video showing how to derive and solve the neutron diffusion equation to determine the critical mass of an atomic bomb here th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
_Comprehensive_ yet not *_abstruse!_* thanks so much
p.s. Frequent misuse of the term "critical mass"? I found that distracting. Such as when, for example? So many social dynamics include this notion, along with _criticality_ and _tipping point._
I was referring to the non-technical use of the term "critical mass." In the corporate world is widely used as a way to say "all you need for something to happen is a critical mass" as having more people for a task is all that matters. I think this misses the point of the meaning of the borrowed term and also misses the opportunity to use it correctly: organizations want something to happen they need the minimum number of people but that is not enough, they also need the right conditions. This is the exact definition of criticality, not critical mass. In the original script and recording I had all this explained but during the editing this sounded more like a rant than a useful comment, cutting the flow of the video, so I took it out. Does this explanation make it more clear? Sorry that it got a bit long.
@@jkzeroYes, indeed. It caught my attention because I'm pre-occupied by how _"common usage"_ can distort discourse!
So thanks for this: _" "all you need for something to happen is a critical mass"._
To be honest, I was trolling one particular sort of fish, so apologize if my question seemed cryptic and over-broad.
Addendum? I read your _" they need the minimum number of people but that is not enough, they also need the right conditions"_ with great interest!
An hour ago (quite literally!) I inserted the following into "notes to myself": _"What if there's an analogue of quantum mechanics in the domain of social cognition? What if, as light can be explored as wave and/or as particle, when observed one way a certain opinion seems perverse and illogical, while observed another way it seems antagonistic and oppositional? Then under the latter conditions, social transactions will most probably only amplify conflicts!"_
_thanks for your time!_ good of you
/bdt
p.s. grade 3 (age 9?) I pondered _"238 this, but 235 _*_that_* ... what's going on?!" 🙂
@@BenTrem42 I will need help here, I do not understand the comment
@@jkzeroApologies. But I'm sure some is clear.
_"caught my attention because I'm pre-occupied by how "common usage" can distort discourse!"_
please explain how to solve the equation shown at @7.30
I published the promised video earlier this year, here it is: th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
Thanks
Thanks to you for watching and welcome to the channel
Amazing what you can learn on TH-cam
I am glad you liked the video, make sure to check there rest of the playlist on nuclear weapons or the currently running series on quantum mechanics
I think the "Fat Man" bomb casing was not a "Soccer Ball" A soccer ball is a "Truncated Icosahedron" It has 12 pentagons and 20 hexagons. In this object the "dihedral angels" are different at the intersection of the Pentagons and the Hexagons and the intersection of hexagon on hexagon. Where the pentagon is adjacent to a hexagon the dihedral angle is 142,62 degrees. Where the hexagon is adjacent to a hexagon the angle is 138.18 Secondly, the area of each polygon is different. Hence you would have different quantities of explosives arranged around the core at different angles. This also means the dihedral angle planes do not split the center of the objects circumscribing sphere. All in all this says that a soccer ball would not work.
I think and I saw once a picture of the bombs casing. It was a "Deltoidal Hexecontahedron". This is an object with 60 kite shaped polygons. They form a sorta stellated dodecahedron. This would avoid the problems described above.
I think the movie got it wrong. Let me know your thoughs.. Thanks, Hamp Stevens
wow, you really made me think deep here, thanks for that! I am not sure when/where in the video I said that the explosive lenses had the shape of a soccer ball, I used the soccer ball only as a reference of the size of a bare uranium core not the shape of the high explosives. Could you point out where this was inferred from in the video?
@@jkzero You're being all too polite. I take the poster as being psychotically pedantic. lol
@@mkor7 honestly, I love pedantry, I can reach high levels of what you call being psychotically pedantic, although as a kid I learned (the wrong way) to keep it to myself
Please show neutron diffusions equations
The video walk-through solving the neutron diffusion equation has received way more support than expected, great to find more people interested in the stories but also in the calculations. It is in the pipeline, coming soon.
promise fulfilled: solving the neutron diffusion equation step by step th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
1:33 I'm kind of sick of this myth, Hahn and Strassmann guessed very well what they had stumbled into.
Hahn and Strassmann guessed very well that they were getting Barium, but they have no explanation for it. At least the letters that Hahn wrote to Meitner show that he was in need of a physical explanation.
@@jkzero The very fact that in the letter he dismisses fission(although he doesn't use that word) as an explanation is proof enough that he had thought of it.
I mean, if you make a discovery that conventional science says is impossible but it's staring you directly in the face, and you phone a friend who is the expert in the matter to consult her about what else could be going on, who made the discovery? You or the friend who reviewed your data?
It actually drives me nuts because Hahn was actually doing good science in that he didn't seek to jump to a conclusion.
ALSO READ: the Wikipedia-article "German nuclear program during World War II".
It would be interesting to know "how was it determined that Uranium 235 and Plutonium 240(?), we're the candidates for the bomb?". Why not lead? Potassium? Etc, etc"
Also, what
several viewers have asked a similar question: out of all the elements of the periodic table, what makes Uranium 235 and Plutonium 239 special for the bomb? I will add this to my long list of videos in the pipeline, thanks for the suggestion. I am curious to know what brings viewers to the channel, were you searching for something in particular or the 'mighty algorithm' found you?
I am an electrical engineer with 40 years experience. For many years, I've been interested in the Manhattan story and certainly more interested after watching the movie Openhiemmer. Your critical mass video fascinating as you address questions that are in the realm of my grasp(barely)...and you explain who figured it out. It is amazing how those brilliant scientists used new understanding to invent the bomb(with it's horrific implications). Well, back to my questions. I've not seen any discussion "how was it discovered that Uranium and Plutonium were the candidates?". For example where there are number of research activities worldwide to analyze those elements within the periodic table for fissil properties? How is it known that fission will release large energy? How was it known, or speculated,, hydrogen fusion would release 1000(?) times more?
To your original question.... the "algorithm" found me.... but the phrase "critical mass" allows me to find you again...
@@DESERTCB1 are you familiar with The Making of the Atomic Bomb by Richard Rhodes? there you find more details than expected, it is a terrific account of many things that most documentaries would not dare to get into. There is the story of how Leo Szilard proposes a series of experiments checking all the elements of the periodic table under neutron bombardment. In parallel, Fermi and his team in Rome did exactly that. Later with the famous Bohr-Wheeler paper, the search narrows down. I should definitely make a video about this in the future
@@DESERTCB1 oh the almighty algorithm, I am glad it has reached to so many people interested in these topics beyond the classic story but accompanied with some real calculations; I am very happy with the interest in the math and physics, in addition to the cool narratives
Does a nuclear chain reaction count as perpetual motion?
to answer this you should ask yourself: "does the reaction stop?"
I would like to know about the first experiments of nuclear fission when they did not know about the consequences of doing so...
I cannot guarantee to be able to fulfill all the requests but I always open to collecting suggestions, thanks.
Likewise. At the moment the only analogue for me is Marie Curie
@@overredrover9430 but she didn't do nuclear fission
@@iAmDislikingEveryShort @amanthatthinks I was thinking of health effects. Having reread your comment I guess you were meaning experiments after that. Apologies, but equally interested.
Anything history I find interesting and this is history about history. As an engineering student I'm interested in physics too, the Dr seems to have combined the two so the channel is extra interesting.
Please show the nuclear diffusion equationn solution
another vote for the solution of the neutron diffusion equation; I was honestly not expecting so many people asking for this so it is now in the to-do list. Coming soon so make sure to subscribe to get notified.
promise fulfilled: solving the neutron diffusion equation step by step th-cam.com/video/DIuoFAW9H3E/w-d-xo.html
wow!
A++
I hope this is a grade and not just a counter (sorry, I have been writing too much code lately); either way, thanks for watching and welcome to the channel
The first fission of uranium was done by Fermi in 1934
true, but he didn't know it, in fact, he got the Nobel Prize for the wrong reason
@jkzero Yes, but not even Otto Hahn understood what was happening. Furthermore, Fermi paved the way for conducting the experiment. In short, someone like Fermi can not be ignored. He, also, created the first nuclear reactor.
Done❤