I’m not sure this would actually work? Is there anything wrong with it? I think it would only work somewhere that doesn’t experience cold winters. The idea that it uses things that are already highly available in a very efficient synergistic combination.

  • badcommandorfilename@lemmy.world
    link
    fedilink
    arrow-up
    5
    ·
    1 day ago

    On a surface look, probably it works. Maybe things like nitrate/phosphate balance or pest/microbe control impact the long term production.

    The problem, as with all CCS strategies is: how do you pay for it? Maybe you can sell those products for a rate that covers the labour and wear and upkeep of the system? It might just be more cost effective to take the carbon-free energy and use it to displace fossil fuel consumption…

    • jaykrown@lemmy.worldOP
      link
      fedilink
      arrow-up
      4
      arrow-down
      1
      ·
      1 day ago

      Excess energy sale, biochar, animal feed, fertilizer sales. Along with carbon capture credits if somewhere that pays for that.

    • jaykrown@lemmy.worldOP
      link
      fedilink
      arrow-up
      2
      arrow-down
      1
      ·
      1 day ago

      Oh I also forgot, technically you could probably raise fish in the pond as well, but I don’t know if they’d eat all the azolla. The point also is to keep the pond shallow, less than 10 cm, to make it easier to construct, harvest, and manage.

  • jaykrown@lemmy.worldOP
    link
    fedilink
    arrow-up
    2
    arrow-down
    1
    ·
    1 day ago

    Master Plan: Agrivoltaic Azolla Cultivation (Simplified)

    A practical, low-cost system that uses solar panels and floating water ferns (Azolla) to capture carbon and generate profitable products.

    The 4-Step System Loop

    1) Shallow Clay Ponds

    • Setup: Dig flat, shallow trenches (~10 m wide) lined with local clay.
    • Water depth: Keep at 5–10 cm to minimize weight and water use.
    • Flow: Use gravity and simple plastic gates to slowly drift ferns toward the harvester.

    2) Solar Panel Canopy (Agrivoltaics)

    • Shade: Mount solar panels to block 40–50% of harsh midday sun, reducing fern sunburn.
    • Cooling: Pond evaporation cools panels, improving efficiency by up to 12%.
    • Power: Panels generate 100% of facility electricity.

    3) Automated Squeeze Loop

    • Skim: Automated paddle wheels continuously collect grown ferns.
    • Squeeze: High-torque electric screw press reduces moisture from ~95% to ~50%.
    • Recycle: Nutrient-rich juice is piped back into ponds, recycling ~90% of fertilizer.

    4) Solar Drying & Final Products

    • Dry: Sun-dry squeezed biomass in simple plastic tunnel greenhouses.
    • Outputs:
      • Biochar: Bake dry fern without oxygen to lock carbon away.
      • Animal feed: High-protein dry ferns for livestock and fish feed.
      • Fertilizer: Pelletized fern to replace synthetic nitrogen fertilizer.

    Estimated Yearly Yields (Per 1 Hectare Pilot)

    • Solar energy: ~600,000 kWh clean power
    • Biomass: ~35–40 tons dry Azolla
    • Carbon captured: ~110 tons CO₂e sequestered
    • Water & nutrients: 100% recycled closed loop