Everything Everywhere Daily: History, Science, Geography & More - The Trinity Test (Encore)
Episode Date: May 11, 2023On July 16, 1945, at 5:29 am, 35 miles southwest of Socorro, New Mexico, the world’s first nuclear bomb was detonated. This was the culmination of the Manhattan Project, one of the largest and mo...st expensive programs in world history. Yet, just before the event, the scientists and engineers who worked on the project weren’t entirely sure it would work and, if it did, just what the results would be. Learn more about the Trinity Test, the world’s first atomic bomb detonation, on this episode of Everything Everywhere Daily. Sponsors BetterHelp is an online platform that provides therapy and counseling services to individuals in need of mental health support. The platform offers a range of communication methods, including chat, phone, and video sessions with licensed and accredited therapists who specialize in different areas, such as depression, anxiety, relationships, and more. Get 10% off your first month at BetterHelp.com/Everywhere ButcherBox is the perfect solution for anyone looking to eat high-quality, sustainably sourced meat without the hassle of going to the grocery store. With ButcherBox, you can enjoy a variety of grass-fed beef, heritage pork, free-range chicken, and wild-caught seafood delivered straight to your door every month. Visit ButcherBox.com/Daily to get 10% off and free chicken thighs for a year. InsideTracker provides a personal health analysis and data-driven wellness guide to help you add years to your life—and life to your years. Choose a plan that best fits your needs to get your comprehensive biomarker analysis, customized Action Plan, and customer-exclusive healthspan resources. For a limited time, Everything Everywhere Daily listeners can get 20% off InsideTracker’s new Ultimate Plan. Visit InsideTracker.com/eed. Subscribe to the podcast! https://link.chtbl.com/EverythingEverywhere?sid=ShowNotes -------------------------------- Executive Producer: Charles Daniel Associate Producers: Peter Bennett & Thor Thomsen Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Update your podcast app at newpodcastapps.com Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Facebook Group: https://www.facebook.com/groups/everythingeverywheredaily Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/ Learn more about your ad choices. Visit megaphone.fm/adchoices
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On July 16th, 1945, at 529 a.m., 35 miles south of Socorro, New Mexico, the world's first atomic bomb was detonated.
This was the culmination of the Manhattan Project, one of the largest and most expensive programs in world history.
Yet, before the event, scientists and engineers who worked on the project weren't entirely certain it would work, and if it did, just what the results would be.
Learn more about the Trinity Test, the world's first atomic bomb detonation, on this episode of Everything Everywhere Daily.
Do you ever climb into bed ready to sleep only to have your mind start racing the moment your head hits the pillow?
Thoughts bouncing around, replaying the day or jumping ahead to tomorrow?
That is exactly why Catherine Nikolai created Nothing Much Happens.
Each episode is a gentle, cozy bedtime story where, well, nothing much happens.
No drama, no tension, nothing you need to follow closely.
Just soft narration, calming repetition, and soothing sensory details designed to help your mind slow down and your body relax.
It's not about entertainment.
about rest, and millions of listeners around the world use it every night to quiet their thoughts
and finally fall asleep. If you've ever struggled to shut your brain off at night, this might be
exactly what you've been missing. You can listen to Nothing Much Happens wherever you get your
podcasts. Episodes are every Monday and Thursday. The story of the Manhattan Project is not one that
can easily be covered in a single episode of this podcast. The cost of the project was staggering
at a time when a billion dollars was still a lot of money. The number of people who were
worked on the project was likewise staggering, especially considering that the United States was in the
middle of a globe-spanning two-front war. While the theoretical science behind making a bomb was known,
it was a far cry between knowing it could theoretically be done and actually doing it. There were
several debates amongst the scientists in the Manhattan Project as to how a bomb could and should
be built. There were differing theories as to what course of action they should take. It wasn't just a
matter of what could work, but also what would be the easiest to build and the most effective.
There were two competing designs that were debated in the program.
And before I get into what these designs were, I need to explain the concept of critical mass and supercriticality.
For a nuclear reaction, you need to have an isotope of some radioactive element, which is considered fizzile.
A fizzile isotope is one that will split after capturing a neutron.
In the process of splitting, it will then give off more than two neutrons on average.
Those neutrons will split even more atoms, ejecting more neutrons, causing a chain reaction.
However, the ability of that reaction to sustain itself requires a certain number of that isotope,
and in particular a certain density of that isotope.
If the neutrons which are expelled after an atomist split aren't hitting more fizzile atoms,
the chain reaction will not continue.
The amount you need to have a self-perpetuating chain reaction is known as its critical mass.
A self-perpetuating chain reaction is great if you're running a nuclear reactor,
but it isn't that helpful if you want to make a bomb.
In that case, you need an even greater rate.
amount to achieve supercriticality. At supercriticality, the growth of the reaction grows exponentially
and it's a runaway process. On one hand, this can be pretty easy to do. Just get a sufficient
amount of a fissile isotope all in one place and you can hit supercriticality. On the other hand,
that's really dangerous. You want to be able to create this runaway chain reaction on demand
and not have it happen when you don't want it to happen. So the designs for the first atomic bomb
were different means to achieve supercriticality.
When Robert Oppenheimer and his team of scientists first began to debate their options,
the first and most popular choice was a design known as a gun-type fission weapon.
The way it works is actually really straightforward.
You have two different parts, one is called the target and the other is called the projectile.
The projectile would consist of nine rings made up mostly of uranium 235.
The projectile would be forcefully expelled by conventional explosives down a barrel of a gun
towards a cylinder of uranium 235.
When the projectile crashes into the target,
its total mass would achieve supercriticality,
and you have yourself an atomic explosion.
This gun-type bomb was the design used for the Little Boy bomb,
which was dropped on Hiroshima.
From an engineering standpoint, it was rather straightforward.
In fact, this bomb design was never tested once
before it was actually used in combat.
The scientists and engineers were so confident that it would work
because, as they said, it was just math.
However, the gun-type design was not the only one that was proposed.
Richard Tolman, a physicist at Caltech, proposed another design called an implosion-type device.
In this device, you would have a conventional explosion in the shape of a sphere,
and inside the sphere, you'd have something called a seed which was made up of fizzile material.
The explosion would compress the seed, and the compression would increase its density,
allowing it to achieve supercriticality.
The implosion device didn't initially get much support because it was considered too complex.
The scientists also weren't just looking at uranium 235 as a fizzile material.
They were also looking at plutonium 239.
The plutonium 239 version of the little boy bomb was known as the thin man,
mostly because it was very long and thin.
However, a plutonium gun-type bomb wasn't very practical.
The thin man needed to be at least 17 feet or 5.2 meters long.
There weren't any planes that could carry it without being modified, and even then, the bomb wouldn't be very aerodynamic after it was dropped.
There was also a much greater risk of an accidental detonation with a plutonium gun-type bomb.
This resulted in the reconsideration of Tolman's implosion idea.
On paper, implosion worked really well, far better than gun-type bombs.
It results in a faster reaction, which results in more energy release for the same amount of fizzile material.
The problem was the engineering of actually building something that could implode properly.
Nothing like this had ever been built before, and the mathematics behind it weren't really that
well understood. They went ahead with the development of an implosion device.
And here I should note that the real challenge in the Manhattan Project, and the thing where
most of the money was spent, was on the enrichment and creation of uranium 235 and plutonium
239. That was 80% of the budget where the vast majority of the manpower was put.
The uranium 235 was created in Oak Ridge, Tennessee, and the plutonium was created in Hanford, Washington.
If you remember back to my episode on if the Nazis came close to creating an atomic bomb,
Werner Heisenberg at first didn't believe the news when he heard it,
because he knew the cost of enriching that much uranium would have been prohibitively expensive.
Because it was so difficult and costly to make,
enriched uranium 235 and plutonium 239 were the most expensive substances on Earth in the 1940s.
In 1944, the idea was floated of testing one of the implosion devices because the engineering was so tricky.
Oppenheimer and the other scientists wanted to do a test, but the head of the Manhattan Project, General Leslie Groves, was concerned about the cost.
He didn't want to waste valuable plutonium.
In fact, they initially tried to find ways to recover plutonium, which wasn't spent, and also considered doing a much smaller explosion.
However, they eventually realized that if the test was to be meaningful, they would have to do a test on a par with what the bomb would have
eventually be asked to do. In March of 1944, Groves gave approval for a full-scale test,
with his biggest concern being that of explaining to a congressional committee how he blew a billion
dollars with a plutonium if the test failed. Approval for the test occurred well before they
actually had anything ready to detonate. However, that time was necessary just to find a place to
conduct the test and build the necessary facilities. The site they selected in September of 1944
was in the Alamagordo bombing range in New Mexico. It was a federally owned property that was flat,
with little danger of fallout landing on civilians. The site was dubbed the Trinity site by Robert Oppenheimer
after a poem from the 17th century English poet John Dunn. An entire base was built for conducting
the test with an ever-growing number of people working at it through late-1944 and into
1945. They actually built an enormous steel shell that the bomb was initially going to be put inside.
It was nicknamed Jumbo, and its purpose was, in the event,
event of a failure, it would contain all the plutonium inside so it could be reused. In the end,
however, it was never used because it would have interfered with the blast data from the detonation,
and it probably wouldn't have worked anyhow. It weighed over 200 tons, and at the time,
it was the largest object ever transported by rail. The camp also created special bunkers,
viewing areas, and special high-speed cameras were developed to capture the explosion. Because of all
the unique devices required to record and observe the test, they actually had a rehearsal explosion
before the actual explosion. On May 7th, over 100 tons of conventional explosives were detonated
on a 20-foot-high wooden platform. It turned out that the rehearsal was necessary, as it was
accidentally detonated two-tenths of a second before it was supposed to. And that may not sound like a lot,
but when you have cameras filming at thousands of frames for a second, that becomes really important.
Likewise, they found many problems with the communication and observation platforms that they had
set up. As the test site was being readied, the bomb, which became known as the gadget,
was being assembled. The gadget was to go on top of a 100-foot or 30-meter steel tower.
When the gadget was hoisted to the top of the tower, they literally had a truck full of
mattresses below it in case it was dropped. The final arming of the device took place at 10 p.m.
on July 15th. There were about 450 people, including VIPs, scientists, and soldiers,
who were observers for the first test. Here I should note that there was still a great deal of debate
as to what would happen. Up until now, everything was still just theory.
Even some very esteemed nuclear physicists like Enrico Fermi and Edward Teller thought that there was a very
small but very real chance that the device would cause some sort of chain reaction that could destroy
the entire atmosphere of the Earth or maybe just the state of New Mexico. People observing the
test set up a betting pool for the actual size of the blast in equivalent to tons of TNT. The bets ranged
from zero, a total dud, to 45 kilotons by Edward Teller. Oppenheimer himself thought it would be only
0.3 kilotons. There were 50 cameras set up, both still and moving pictures to capture the
explosion, and one camera was capable of taking 10,000 images per second. They actually wanted
better weather, which was forecast for July 18th through the 21st, but politics got in the way.
Harry Truman was scheduled to attend the Potsdam conference with Stalin and Churchill
starting on July 17th, so July 16th was the date that was chosen. The detonation was scheduled for
4 a.m., but light rain postponed it for an hour and a half. At 529 a.m. and 21 seconds, the world's
first atomic bomb was detonated. The explosion was far larger than most of the scientists had predicted.
In 2021, it was remeasured at 25 kilotons of TNT using the original data. It was the largest
explosion in human history at that time, over 10 times greater than the power of the Halifax
explosion. Observers who later recorded the recollections of the blast, all common
on the brightness of the light and the power and heat of the blast. One of the unforeseen consequences
of the blast was that the sand underneath the bomb had been turned into a glass. The glassy substance
had been dubbed Trinotite, and Trinotite was actually collected by people for years who wandered out
to the test site until it was eventually made illegal by the U.S. government. Trinotite, which was
collected before the ban, is still legal, and you can actually purchase small samples of it online today.
The gadget, which was detonated at the Trinity test site, was the same type of bomb which was dropped on the
city of Nagasaki. The bomb dropped on Hiroshima was a uranium-based gun-type device, which was never
used again because the implosion devices proved so much more effective. The Trinity test was eventually
made public after the bombing of Hiroshima, but oddly enough, scientists at the Kodak Corporation had
figured out there must have been a detonation on U.S. soil before it was actually announced. Kodak customers
began complaining about spots appearing on sensitive film made for X-ray machines just about a month
after the Trinity Test. And it had to do with the paper used in the cardboard boxes, which came
from contaminated trees in Indiana, which had trace amounts of fallout. Today, the Trinity Test site
is a National Historic Site, and there's a monument that was erected in 1965 at Ground Zero.
You can visit the site, but you can only do so two days each year. It's open on the first Saturdays
in April and October. The reason why access is restricted is that it is still within the boundaries
of the White Sands Missile Testing Range, and there are active missile testing range. And there are active missile
tests going on on a regular basis. Once the Trinity test took place, it basically marked the end of
the Manhattan Project. Their mission had been accomplished. The initial joy of a successful test quickly
turned somber when they realized the implications of what they had done. The mood was perhaps best
summarized by Robert Oppenheimer himself, who years later wrote of the Trinity test, quote,
We knew the world would not be the same. A few people laughed, a few people cried, most people
were silent. I remembered the line from the Hindu scripture, the Bahavagita. Vishnu is trying
to persuade the prince that he should do his duty, and to impress him, takes on his multi-armed
form and says, now I am become death, the destroyer of worlds. I suppose we all thought that,
one way or another. The executive producer of Everything Everywhere Daily is Charles Daniel. The
associate producers are Thor Thompson and Peter Bennett. I just want to thank everyone, including
the show's producers, who support the show over on Patreon. If you'd like to support the show,
just head over to patreon.com, which is currently the only place where you can get show merchandise.
Also, if you want to talk to other listeners about the show,
head over to our Facebook group or Discord server, both of which have links in the show notes.
