• Blue_Morpho@lemmy.worldEnglish
    9112·
    3 months ago

    Uranium generates that energy by fission. The hydrogen in sugar could generate huge amounts of energy if fused.

    • TheTechnician27@lemmy.worldEnglish
      612·
      3 months ago

      And this boulder could generate huge amounts of energy if I pushed it up to the top of Mt. Kilimanjaro and let it roll down.

      44 upvotes and 0 downvotes for a comment that doesn’t understand that energy density measurements like this tend to measure the useful energy of a system.

      • Blue_Morpho@lemmy.worldEnglish
        72·
        3 months ago

        Using the rule of thumb, anything heavier than iron requires energy input to fuse. So you lose energy fusing uranium.

      • davidgro@lemmy.worldEnglish
        31·
        3 months ago

        Serious answer: A huge negative amount. Anything above iron requires energy to fuse (which is why it produces energy from fission.) and I’m pretty sure nothing with 184 protons could be stable enough to count as being produced - the nuclei would be more smashed apart than merging at that point.

      • PunnyName@lemmy.worldEnglish
        49·
        3 months ago

        Ask Hiroshima and Nagasaki.

        In alphabetical order.

        Edit: oops, those are fission, my bad

        • Blue_Morpho@lemmy.worldEnglish
          171·
          3 months ago

          Those are fission. Fusion bombs don’t fuse uranium. They use a fission bomb to fuse Lithium.

              • peoplebeproblems@midwest.socialEnglish
                6·
                3 months ago

                I mean if we really want to be technically accurate here, the lithium is just a moderater for the hydrogen isotopes to fuse.

                But for me it gets fuzzy when looking at the reaction.

                LiD is 4 protons, 8 neutrons. Add a new neutron, and bam, you have 4 protons and 9 neutrons. But that’s where it gets weird to me. The lithium needs to decay or something into a tritium and dueterium which forces the tritium to fuse with the existing dueterium in the LiD molecule? Clearly the neutron has enough energy to transfer into one of the atoms to increase the chance of tunneling actually occuring.

                • ChickenLadyLovesLife@lemmy.worldEnglish
                  4·
                  3 months ago

                  The only real purpose of the lithium deuteride is that it’s a dry, shelf-stable, room-temperature fuel. The very first hydrogen “bomb” (actually a building-sized device) used supercooled liquid hydrogen as the fusion fuel, but this was obviously not practical for a deliverable bomb.

          • frezik@midwest.socialEnglish
            2·
            3 months ago

            Oh, they do, but not as the primary or secondary. You can wrap depleated uranium around the core to capture fast neutrons that are leftover from the rest of the process. Changing the number of layers is how you can dial in a desired yield.

    • nialv7@lemmy.worldEnglish
      201·
      3 months ago

      It’s disappointing that natural selection didn’t figure out fusion.

      • WhiskyTangoFoxtrot@lemmy.worldEnglish
        15·
        3 months ago

        It figured out photosynthesis instead. Why do your own fusion when you can just take advantage of the fusion that’s already happening?

      • SkyeStarfall@lemmy.blahaj.zoneEnglish
        4·
        3 months ago

        It’s good it didn’t, otherwise it’s possible that all the hydrogen in the ocean would be fused into helium by now

        Well, more likely it would significantly heat up earth due to the amount of energy released first, cooking everything/starting an endless cooking->extinction->cooling cycle

      • Trollception@sh.itjust.worksEnglish
        41·
        3 months ago

        We have fusion (hydrogen) bombs. We just haven’t figured out how to maintain and efficiently harness it for energy.

    • Redex@lemmy.worldEnglish
      13·
      3 months ago

      Whilst I get your point, their point is still valid in the sense that you just can’t extract that energy from gasoline in a more efficient manner than just burning it. For practical purposes, gasoline truly is that much less energy dense.

    • suoko@feddit.itEnglish
      11·
      3 months ago

      For comparison:

      • Chemical combustion of uranium: ~4.7 MJ/kg
      • Nuclear fission of uranium-235: ~83.14 TJ/kg (or $ 83.14 \times 10^6 , \text{MJ/kg} $)
      • sga@lemmings.worldEnglish
        8·
        3 months ago

        sadly black holes go to something like 42% conversion (source: some minute physics video i think)

        • hemko@lemmy.dbzer0.comEnglish
          1·
          3 months ago

          That’s quite interesting. Is it because of the light produced when the materia starts spinning around in the accretion disk in very high speeds? I doubt hawking radiation would do anywhere near that much

          • sga@lemmings.worldEnglish
            1·
            3 months ago

            https://youtu.be/t-O-Qdh7VvQ

            No, It is actually the light produced that we can actually use as a energy source, the limiting thing is, before completely loosing its kinetic energy to frictional heat, stuff falls into black hole, from where we can not get anymore energy back. If black hole is stationary, then its 6%, and if its spinning (and assuming the fastest spinning theoretically possible) - 42% (spinning black holes are smaller and have smaller radius of no-return

            • hemko@lemmy.dbzer0.comEnglish
              2·
              3 months ago

              Ahhh alright I was thinking the black hole converting mass to energy for itself, not as if we were to try utilize it

    • dalekcaan@lemm.eeEnglish
      8·
      3 months ago

      In theory, yes. In practice, of those two only fission is currently viable.

    • Ledericas@lemm.eeEnglish
      41·
      3 months ago

      If you can do nuclear fusion yea, it’s more efficient. Cold fusion has been a sci Fi thing for a while; they mostly moved on to antimatter-matter annihilation, and ZPE(seems to be a favorite for sg1)

  • ddh@lemmy.sdf.orgEnglish
    73·
    3 months ago

    If we could consume uranium, you could have a teaspoon’s worth and be done with eating for the rest of your life.

      • Trollception@sh.itjust.worksEnglish
        221·
        3 months ago

        I wonder if that’s actually factual or not. Uranium by itself isn’t too terribly dangerous. It’s the whole fission byproducts thing that’s the buzz kill.

          • chaogomu@lemmy.worldEnglish
            3·
            3 months ago

            Interestingly, no. It’s not the same as if you ate a chunk of lead.

            Lead binds to calcium channels, and then blocks them. This makes it a bit of a neurotoxin. It also accumulates in the bones.

            Uranium on the other hand is one of the heavy metals that the body is good a filtering out of the blood. The body is not as good at expelling the uranium. It accumulates in the kidney. This can lead to kidney disease, and other related issues. And that’s just the chemical toxicity of Uranium. Add in the radioactive side of things, and you have a truly distinct form of metal poisoning.

        • KiwiHuman@lemm.eeEnglish
          9·
          3 months ago

          Also it depends on the isotope of uranium. Something you could find naturally isn’t too dangerous, but something enriched too be used as fuel or for wepons is significantly more radioactive.

    • andros_rex@lemmy.worldEnglish
      1·
      3 months ago

      I have a uranium rock which I could conceivably swallow - probably closer to a tablespoon than a teaspoon. I don’t think any process in my body could extract energy from it.

      Alpha radiation is not too bad. Unshielded helium particles. Like I tell anyone I show my rock too - as long as you don’t eat it, this is safe. (I am a mad scientist who has exposed hundreds if not thousands of children to uranium lol)

      Really, if you could extract the energy from the nucleus of a hydrogen atom, you’d never have to eat again. But also because that’s too much energy for you and you would be dead.

      • dQw4w9WgXcQ@lemm.eeEnglish
        8·
        3 months ago

        Antimatter doesn’t really do anything by it’s own, but if we let 1 kg react with 1 kg of matter (non-anti-matter), we get E = mc2 with m = 2 kg. So 1.8 * 1017 J, or 1.8 * 1011 MJ. If we assume that 10 MJ/kg is represented by about 1 cm, the bar would have to be 1.8 * 1010 cm or about 1.8 * 108 m. A standard A4 piece of paper is about 30 cm tall, so 6.0 * 108 A4 papers are needed. I.e. 600 million papers.

        So we definitely have enough paper, but it would be a very tall stack.

        • Lv_InSaNe_vL@lemmy.worldEnglish
          5·
          3 months ago

          That’s only about 180,000km (~112,000 miles) or just under half way to the moon.

          Also some quick googling says an average desktop printer can print about 30,000 pages per month, so it would take 20,000 months (~1670 years) to print that out. And a typical toner cartridge can print 3,000 pages and costs $80, so it would take 200,000 toner cartridges and cost $16 million.

          Now, those aren’t based on any specific model, just the first result in Google haha

  • ThePyroPython@lemmy.worldEnglish
    12·
    3 months ago

    Yes boss, I did work out the dynamic range of that log amplifier we wanted to use in our next product’s sensor PCB, it’s 80dB.

    The results are over here. (points to a roll of A-4 paper)

    It has 40 data points and only took me 1 week, 10 pencils, and 20 erasers to plot the chart. Yeah I can present it, it’ll take me 10 minutes to roll it out, pin it down, and fetch the A-frame ladder.

    • qjkxbmwvz@startrek.websiteEnglish
      4·
      3 months ago

      This is the real big brain hack with decibels — you can use a linear scale, it’s just that the units are logarithmic instead.

      (Yes I know most people would call a dB axis logarithmic, it’s just a silly comment.)

      • _stranger_@lemmy.worldEnglish
        3·
        3 months ago

        You call this a linear holograph of a non linear phenomenon and earn yourself that promotion.

  • andros_rex@lemmy.worldEnglish
    6·
    3 months ago

    Weird thing I’ve noticed:

    Logs are taught in high school. Absolutely no one seems to remember what they are after the unit test, much less high school. I’ve even reminded other math instructors about how to use them.

    Why do people have such a hard time learning to use and understand logs?

    I love this comic, and it’s going to replace my weird “let’s talk about how this makes the distance between us and Alpha Centauri, and us and Earendil easier to understand” bit.

    • WarlordSdocy@lemm.eeEnglish
      2·
      3 months ago

      I mean I think a lot of it is that at least in America when it comes to Math a lot of the teaching is more about how to use specific formulas and apply them to certain kinds of problems. They don’t really teach you what it is you’re actually doing or why you’re doing it. It just turns into recognizing a type of problem and applying a certain tool to it rather than understanding what that tool is and what it does.

    • blind3rdeye@lemm.eeEnglish
      0·
      3 months ago

      I was thinking the same thing. It’s unfair compare chemical energy to nuclear energy. Coal still kind of sucks, but the hydrogen in the others could definitely be used in fusion…

      • Shayeta@feddit.orgEnglish
        1·
        3 months ago

        It is perfectly fair in the context of “fuel”, a resource used to produce energy. Whether energy is generated via chemical or nuclear reaction is irrelavent in this case.