• elucubra@sopuli.xyz
    link
    fedilink
    English
    arrow-up
    13
    arrow-down
    1
    ·
    5 days ago

    I’m not a rabid anti-nuclear, but there are somethings that are often left out of the pricing. One is the exorbitant price of storage of spent fuel although I seem to remember that there is some nuclear tech that can use nuclear waste as at least part of it’s fuel (Molten salt? Pebble? maybe an expert can chime in). There is also the human greed factor. Fukushima happened because they built the walls to the highest recorded tsunami in the area, to save on concrete. A lot of civil engineering projects have a 150% overprovision over the worst case calculations. Fukushima? just for the worst case recorded, moronic corporate greed. The human factor tends to be the biggest danger here.

    • suigenerix@lemmy.world
      link
      fedilink
      English
      arrow-up
      2
      ·
      edit-2
      5 days ago

      … there are somethings that are often left out of the pricing

      Another example that gets skimmed over or ignored is the massive cost of decommissioning a nuclear power plant. It typically ranges from $280 million to $2 billion, depending on the technology used. More complex plants can be up to $4 billion. And the process can take 15 to 30 years to complete.

    • humanspiral@lemmy.ca
      link
      fedilink
      English
      arrow-up
      2
      ·
      5 days ago

      there is some nuclear tech that can use nuclear waste as at least part of it’s fuel

      Those are less competitive, and salt reactor attempts have historically caused terminating corrosion problems. The SMR “promise” relies on switching extremely expensive/rare/dangerous plutonium level enriched fuel, that rely on traditional reactors for enrichment, for slightly lower capital costs.

    • Flatfire@lemmy.ca
      link
      fedilink
      English
      arrow-up
      3
      ·
      5 days ago

      Not an expert, but molten salt reactors are correct. MSRs are especially useful as breeder reactors, since they can actually reinvigorate older, spent fuel using more common isotopes. Thorium in particular is useful here. Waste has also been largely reduced with the better efficiency of modern reactors.

      Currently, Canada’s investing in a number of small modular reactors to improve power generation capacity without the need to establish entire new nuclear zones and helps take some of the stress off the aging CANDU reactors. These in particular take advantage of the spent fuel and thorium rather than the very expensive and hard to find Uranium more typically used. There’s been interest in these elsewhere too, but considering how little waste is produced by modern reactors, and the capacity for re-use, it feels pike a very good way to supplement additional wind and solar energy sources.