• Eheran@lemmy.world
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    4 months ago

    It will be radioactive forever. The question is where you put the threshold, which is fairly arbitrary.

    • toast@retrolemmy.com
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      4 months ago

      Eh, it could be non-radioactive next week. That’s not very likely, but it could be

      • FiskFisk33@startrek.website
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        4 months ago

        eh, i could randomly teleport to the moon suddently, but things like theese are unlikely enough to be in effect completely and utterly impossible.

        • EddoWagt@feddit.nl
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          4 months ago

          I could also phase through a wall by sheer coincidence of all my molecules missing the molecules of the wall, but yeah, not going to happen unfortunately

    • weker01@feddit.de
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      4 months ago

      If you only think about half live then yes it would be radioactive forever but in reality after a long time every atom would’ve decayed into non radioactive elements.

      You can even calculate the expected time it would take for the random process of decay to terminate.

      • Eheran@lemmy.world
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        4 months ago

        “after a long time” - that is exactly my point. Where do you draw the line? It will never be non-radioactive, which the headline suggest would be the case in 1’500 years. As far as we know, everything might decay after some time. It will always have some Radon get trapped in it. Scatter some cosmic rays. Blablabla.

        • Tlaloc_Temporal@lemmy.ca
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          4 months ago

          By that logic, everything withing a few kilometers of the surface is radioactive, especially all life. That’s not a useful definition of radioactive.

    • drislands@lemmy.world
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      4 months ago

      I wonder how long it would take for the radioactivity to be indistinguishable from the atmospheric average.

    • flamingo_pinyata@sopuli.xyz
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      4 months ago

      Um, Chernobyl is still extremely radioactive. You probably mean the exclusion zone which is really not that bad, there’s even tourists going there. But it’s still not recommended to live there due to cumulative exposure.

      • AwkwardLookMonkeyPuppet@lemmy.world
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        4 months ago

        So the site itself is still deadly, but the areas around it are not? Would that be the case for a nuclear attack as well? Like ground zero would stay deadly but the rest of the city would be safe a few decades later? I just realized that I don’t actually know very much about nuclear fallout. How are Hiroshima and Nagasaki safe?

        • weker01@feddit.de
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          4 months ago

          Complex topic. It would depend on the bomb in question. Some are more “dirty” than others.

        • whotookkarl@lemmy.world
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          4 months ago

          The clouds of radioactive gases carry radiated dust particles that are carried by winds and settle on the ground, roofs, etc (fallout). That’s why after Chernobyl or the Japanese cities were attacked it was very important which way the wind was pushing the clouds carrying the tiny debris, ash, and dust and how the Chernobyl disaster was detected by other countries in the path.

          You probably also want to avoid trying to grow any crops in the area because one way to deal with the radioactive dust is to bury it under the top soil, and buildings that have been closed since Chernobyl that still have the dust trapped inside are still very dangerous.

          Edit: the bombs in Japan exploded high above the ground to maximize damage and minimize fallout. The gases were carrying less radiated particles, and mostly dispersed after the initial blast or carried by winds. The gases over Chernobyl kept going until the fires were out.

        • zaph@sh.itjust.works
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          4 months ago

          It’s been a couple of decades since I watched the documentary so maybe my memory is betraying me but from what I remember the bombs dropped on Japan didn’t touch the ground. They detonated in the air so there technically isn’t a ground zero.

        • ✺roguetrick✺@lemmy.world
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          4 months ago

          Generally the really nasty gamma emitting fission products lose their nastiness after a couple of months. Their half lives tend to be counted in hours.

        • Xavienth@lemmygrad.ml
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          4 months ago

          They overturned the dirt in the exclusion zone to bury the fallout so that it’s less of a possibility for it to move around. You wouldn’t want to live there, drink from the groundwater, farm there, etc.

    • bouh@lemmy.world
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      4 months ago

      Marie Curie studied radioactivity with pure and very active materials with no protection. The radioactivity of the notebook is indirect radioactivity, that is material that becomes radioactive after being exposed to powerful ionizing radiations. It must be noted that the notebook may not be deadly radioactive. And if it will be for 1500 years, it won’t be deadly for 1500 years. For reference, bananas tend to be radioactive too. And you are exposed to ionizing radiations when you take the plane.

      Chernobyl had two reactors burn iirc. Most of the radioactive material was in the reactor, but the fire made smoke out of radioactive materials. The quantity of smoke, in kg, that go out was significant, but it got diluted in the atmosphere and spread. Which means there wasn’t so much dust, in mass, that got in any one place. The dust is also not only uranium, but a combination of uranium and materials that were contaminated like the notebook. With the rain, the dust was washed and distributed more, and with the time, materials become less and less radioactive.

      Both the book and chernobyl are not dangerously radioactive. But because of the nature of radioactivity, care must always be taken.

      • ✺roguetrick✺@lemmy.world
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        4 months ago

        They’re contaminated, not neutron activated. The curies didn’t get to the point of developing an unshielded nuclear reactor that would sufficiently neutron activate their stuff. They just liked to carry around radium and polonium which also have decay products that themselves are radioactive and they contaminated everything.

        • bouh@lemmy.world
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          4 months ago

          Thanks for the precision. Still, the result is the same I’m sure.

          • CommissarVulpin@lemmy.world
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            4 months ago

            More or less. The difference is that, if they really wanted to, they could very thoroughly clean the notebook and take most of the contamination off. I’m guessing they won’t because a) It’s a historical artifact and they don’t want to risk damaging it, b) the contamination is so low-level that it’s not dangerous as long as you don’t lick it or something, and/or c) there’s a bit of a shock factor in watching a scientist’s notebook make a Geiger counter freak out.

      • _bac@lemmy.world
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        4 months ago

        Ionizing radiation can’t produce secondary radioactivity in materials…

        • bouh@lemmy.world
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          4 months ago

          Well, maybe explain my confusion then, instead of being an ass.

          • CommissarVulpin@lemmy.world
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            4 months ago

            So there’s four types of radiation: alpha, beta, gamma, and neutron. When you’re talking about radioactive materials, it’s almost exclusively the first three. In addition to the inherent danger of the object itself, there’s also the danger of radioactive contamination: not making other things radioactive, but shedding bits of themselves as dust and then that dust getting on other things, or getting ingested/inhaled by humans.

            Active fission reactions, like what goes on in the core of a nuclear reactor (or perhaps messing around with some plutonium and a screwdriver), produce neutron radiation. Neutrons can make other things radioactive, via a process called “neutron activation”, whereby the neutrons bind to the material and change some of the atoms into radioactive isotopes.

            I hope that helps, and feel free to ask me anything else about radiation. I have some education about it thanks to my job, and I’m always happy to help other people understand it more as well.

            • bouh@lemmy.world
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              4 months ago

              I know quite a bit about radioactivity thanks to my studies. I was sure all radiations could activate something, but it turns out I was wrong apparently because I can’t find anything but neutron activation.

              I’m pretty sure alpha, beta and gamma rays can stick to a particle, often bringing it in an unstable state that will force it to release something to get into a stable state. That’s particle physics. And that’s why we call them ionising radiations : because they turn atoms into ions. But my memories are definitely fuzzy, and it was not were I was the best.

              Those radiations may only activate for a too short time to be useful maybe? I don’t know.

            • bouh@lemmy.world
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              4 months ago

              Ha ! Turns out I’m right after all : radioactivation can happen with all type of radiations. But neutron activation is the lowest energy one.

              You are right that it’s probably a contamination for the book though, and not directly an activation (although carbon can be activated and will be found in the book).

              • cinnamonTea
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                4 months ago

                The thing you said that someone disagreed with was calling it ionizing radiation, which is a more general term and describes radiation with enough energy to ionize an atom or molecule, which means stripping off at least one of its electrons. That requires a lot less energy than activating nuclei in an element that is not radioactive to radioactivity. UV light and X-rays are both ionising radiation, but are not from radioactivity and cannot induce radioactivity. Of course a lot of radioactive radiation (α, β, γ) is also too low-energy to activate more nuclei. It depends on the energy of the radiation and the specific element you’re trying to activate (how close it is to being radioactive, so to speak).

                So like CommissarVulpin said - the real danger is more likely to be contamination

                • ✺roguetrick✺@lemmy.world
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                  4 months ago

                  Yeah, like you can activate small amounts of material with alpha particles from a particle accelerator like Cockcroft did or really bombarding them with relatively low energy concentrated alpha particles like Curie’s daughter did, but it’s not generally a major contributing factor to the radioactivity from just being around alpha emitters since you really have to do it very intentionally.

    • Cort@lemmy.world
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      4 months ago

      It isn’t “safe” it’s “safe enough” for limited visits to the exclusion zone and VERY limited visits to the sarcophagus that enclosed the old reactor

        • Wereduck@lemmy.blahaj.zone
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          4 months ago

          I was gonna answer that most animals don’t live as long and reproduce faster than humans (so populations survive despite increased cancer risk), but when I looked into it I found a deep rabbit hole. In the case of wolves, I’m sure plenty died early on, because the populations present appear to have some genetic immune adaptations that protect them from cancer. I know other species (like frogs) have dark skin because the melenin increased the survival rate of the darker frogs at the time of the accident. So that is to say probably a lot of wildlife died, and that natural selection lead to some critters that are pretty resistant to radiation.

    • EddyBot@discuss.tchncs.de
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      4 months ago

      fun fact: the other three reactors in Chernobyl were put in operation again AFTER reactor 4 blew up
      I believe the last one for 14 additional years

      how safe that was is another question though

      • Cethin@lemmy.zip
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        4 months ago

        I think we can safely say with hindsight, it was very safe. Reactor 4 was caused by a fluke of circumstances and a few mistakes. It was otherwise a very safe reactor. Once they understood the failure they are able to adjust protocol to ensure it doesn’t happen again. It made the other reactors even safer.

        The same thing happened with three mile island. Unit 1 safely continued operation until 2019, which only stopped because of financial pressures (competition with Methane), not because anything was wrong.

    • GTG3000@programming.dev
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      4 months ago

      Chernobyl isn’t safe safe, it’s just safe enough for wildlife to survive there, possibly with lowered life span and quality of life.

      Also, there’s a decent danger of radioactive dust coming off the book if it’s handled. It may not be that radioactive, but if it clings to you, or you breathe it in, it will do considerably more damage than if it was all one solid rock that made geiger counters click.

    • RunawayFixer@lemmy.world
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      4 months ago

      The wildlife is just left alone, I wouldn’t call it safe from radiation, they still have a higher incidence of mutations than animals outside the contaminated zones. It’s just that some radiation and no humans, happens to be better for wildlife than no radiation and lots of humans.

  • qjkxbmwvz@startrek.website
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    4 months ago

    It looks like they were super lazy and took the half life of the longest lived isotope of radium (226 — approx 1600 years) minus its age (approx 100 years) to get to 1,500 years.

    • Dr. Bluefall@toast.ooo
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      4 months ago

      I’m guessing we don’t know the particulars of what radium isotope Curie was working with?

  • NutWrench@lemmy.world
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    4 months ago

    There’s a couple of YouTube videos where urban explorers re-visited Chernobyl many years after the accident. They explored the area around the plant and visited the hospital where Russian firefighters were taken after they were exposed to debris from the reactor’s core.

    Their clothing was seriously contaminated and was removed and stored in a room in the hospital’s basement. The explorers visited the basement where the clothing is still stored today. They didn’t get close to the clothing because it is still contaminated. As in, “not safe to enter the room” contaminated.

    • vaultdweller013@sh.itjust.works
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      4 months ago

      It should be noted that big chunks of radioactive materials are generally safe same with just generally high radiation under a certain threshold, we are illuminated by a big ball of fuck you radiation after all. The problem is radioactive dust and particulates, once its in your body you are fucked and its pretty random on what amount will kill you. This is what happened to those Russian dumbasses who dug trenches around Chernobyl, they breathed in radioactive dust and it wreaked havoc on their bodies. This is also one of the main reasons you wear gas masks around such things.

    • dependencyinjection@discuss.tchncs.de
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      4 months ago

      Content below provided by ChatGPT.

      Edit: Is the below information incorrect or y’all just have a stick up your asses over LLMs?

      Marie Curie’s notebooks are still radioactive due to the presence of radium-226, which has a half-life of about 1,600 years. To make her notebook non-radioactive or significantly reduce its radioactivity, the following methods could theoretically be used:

      1. Chemical Removal or Neutralization:

        • Chemical Extraction: This involves using chemicals to extract the radioactive elements from the paper. This process would be complex and potentially damage the paper.
        • Neutralization: This would involve converting the radioactive materials into stable, non-radioactive elements. However, there are no practical methods currently available for neutralizing radium in situ.
      2. Encapsulation:

        • Instead of making the notebook non-radioactive, it could be permanently encapsulated in a material that blocks radiation, such as lead-lined containers or specialized glass. This wouldn’t make the notebook safe to handle without protection, but it would contain the radiation.
      3. Decay Time:

        • Given the long half-life of radium-226, waiting for the radioactivity to decay to safe levels is impractical since it would take thousands of years for the radioactivity to diminish significantly.
      4. Advanced Radiation Mitigation Techniques:

        • There are experimental methods like targeted transmutation, where the radioactive elements are bombarded with particles to induce decay into stable elements. This is highly theoretical and not feasible with current technology for something as delicate as a notebook.

      Practically, due to the historical and scientific value of Marie Curie’s notebooks, they are preserved and stored in controlled environments where they can be studied safely using appropriate radiation protection measures. The best approach currently is to handle and store them with care rather than attempting to decontaminate them.

        • dependencyinjection@discuss.tchncs.de
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          4 months ago

          Care to elaborate?

          I wonder what the issue is? Is it that is can provide wrong information?

          Is it that you don’t see any legitimate use cases for them? As I work as a software developer and CoPilot in Visual Studio has saved us countless hours in writing boiler plate stuff and just solving problems in general.

          Furthermore, the owner has created some pretty amazing tooling utilising LLMs and again, it saves us countless hours in the boring things. Like now if I make a new model in C#. We have something watching the code and that will use LLMs and some custom methods to scaffold changes to about 10-15 files and also create UI components in the client ready for us. All we need to do is update the schema doc for graphQL, run the migrations and update the DB. Then we are good to go. Saves about an hour every time a model is added or changed.

  • hardy
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    4 months ago

    🎶Welcome to the new age, to the new age , la la la la🎵🎶