• skillissuer
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    4 months ago

    there’s not enough lithium on this planet to store enough energy for like half of europe nevermind entire world

    you know how to do this the right way? use pumped-storage hydropower. need more? build more, then dump power into heaters (or better yet heat pumps) on demand from grid since fossil fuel heating will be replaced anyway. (we’re nowhere close to this, but it can sink a lot of energy quickly while not using it at some other times)

    • Fermion@feddit.nl
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      4 months ago

      Pumped hydro is both very geologically limited and environmentally detrimental. That technology alone will not substantially reduce the need for other power storage technologies/ peaker plants.

      • tal@lemmy.today
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        4 months ago

        Pumped hydro is both very geologically limited and environmentally detrimental.

        If you are willing to live with the very considerable impact and are willing to do a costly megaproject, one possibility that I’ve raised before: it’d be possible to go implement Atlantropa, but instead of using it (exclusively) to generate hydroelectric power, as its creator envisioned, use it for pumped storage. The world will never need more energy storage than that could provide.

        https://en.wikipedia.org/wiki/Atlantropa

        Atlantropa, also referred to as Panropa,[1] was a gigantic engineering and colonisation idea that German architect Herman Sörgel devised in the 1920s, and promoted until his death in 1952.[2][3] The proposal included several hydroelectric dams at key points on the Mediterranean Sea, such as the Strait of Gibraltar and the Bosporus, to cause a sea level drop and reclaim land.

        The central feature of the Atlantropa proposal was to build a hydroelectric dam across the Strait of Gibraltar, which would have generated enormous amounts of hydroelectricity[4] and would have led to the lowering of the surface of the Mediterranean Sea by as much as 200 metres (660 ft), opening up large new areas of land for settlement, such as in the Adriatic Sea. Four other major dams were also proposed:[5][6][7]

        • Across the Dardanelles to hold back the Black Sea
        • Between Sicily and Tunisia to provide a roadway and to lower the inner Mediterranean further
        • On the Congo River below its Kasai River tributary, to refill the Chad basin around Lake Chad, provide fresh water to irrigate the Sahara, and create a shipping lane to the interior of Africa
        • Extending the Suez Canal and locks to maintain connection with the Red Sea

        Sörgel saw his scheme, which was projected to take more than a century, as a peaceful pan-European alternative to the Lebensraum concepts that later became one of the stated reasons for Nazi Germany’s conquest of new territories. He envisioned Atlantropa as a way of providing land, food, employment, electric power, and, most of all, a new vision for Europe and neighbouring Africa.

        There are two very considerable issues there:

        • First, dropping the Mediterranean Sea by 200 meters is going to have a very large impact on the coasts of northern Africa and southern Europe. Sörgel considered that desirable, but obviously there are going to be a lot of people who don’t like such a change.

        • Second, if it’s permitted to build structures in this new area – as was originally intended – then a rupture of the dams would produce cataclysmic flooding; we would essentially have recreated the Zanclean flood:

          Ninety percent of the Mediterranean Basin flooding occurred abruptly during a period estimated to have been between several months and two years, following low water discharges that could have lasted for several thousand years.[3] Sea level rise in the basin may have reached rates at times greater than ten metres per day (thirty feet per day). Based on the erosion features preserved until modern times under the Pliocene sediment, Garcia-Castellanos et al. estimate that water rushed down a drop of more than 1,000 metres (3,000 ft) with a maximum discharge of about 100 million cubic metres per second (3.5 billion cubic feet per second), about 1,000 times that of the present-day Amazon River.

          The Royal Air Force bombed two dams in Germany during World War 2 to flood an industrial area in Germany. Russia just blew up a hydroelectric dam in Ukraine that caused a mess and water to drop upstream by 2 meters. If such a dam were to be attacked in a war like that, it would be horrendous. We’d be talking about a water depth difference a hundred times that and a far larger area.

        EDIT: And a third, I suppose – if you take water out of the Mediterranean via evaporation and pumping, it will eventually wind up elsewhere, and we live in an era where sea level rise is already a concern, so it’ll cause sea level rise elsewhere. Would eliminate concerns about sea level rise for the Mediterranean, though…

        • Fermion@feddit.nl
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          4 months ago

          There is also the issue that if building nuclear plants takes too long and is too expensive to be the solution, then such a project would also be too late to matter. Also transmission losses likely mean this is a solution for much less of the world population than you think. If we had a truly global lossless grid, then we would need much less energy storage to begin with.

          Impracticalities aside, absurd geoengineering what-ifs are entertaining. Thanks for sharing.

      • skillissuer
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        4 months ago

        at least it works at scale relevant to grids. there are other interesting devices that store high grade heat in things like molten silicon or sand, then convert it to electric energy again, but it’s rather at prototype scale now i think. power to hydrogen is fine if it’s replacing hydrogen from natural gas, but it’s wack for storage of energy

    • Semi-Hemi-Lemmygod@lemmy.world
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      4 months ago

      Lithium Ion is more advanced battery technology because it’s got high energy density which means it’s used in consumer electronics. Lower energy density technologies exist with better properties for storing at grid scale. They’re heavier and bigger than lithium ion batteries, but can store energy a lot longer and use much more available materials. One example is Form Energy’s Iron/Air battery, which uses rusting iron to store electricity for hundreds of hours.

    • MrVilliam@lemmy.world
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      4 months ago

      there’s not enough lithium

      I am hopeful that developments in sodium ion battery tech will yield different strategies. The weight and energy densities vs cost and abundance mean that it makes more sense (at this time at least) to reserve lithium ion battery tech for more mobile use cases like handheld devices and EVs, but use sodium ion battery tech for things like grid storage or home energy management solutions. I dream of a day in the next decade or two in which virtually nobody bothers to have a generator for emergency home power and instead opts for a UPS with inverters and chargers hooked up to a home battery, allowing not only emergency power, but a “smart” system to power the home via battery during high grid demand and charge during low demand, normalizing grid supply curves and making power bills cheaper for all. The path to this starts with big scale early adopters like hotels and apartment buildings, which could easily supplement energy needs through solar panels on their large roofs at the same time.

      For all the enshittification we’re seeing across most industries, I am cautiously optimistic that we might be living at the edge of an energy revolution. We may see fucking huge fundamental changes to our energy infrastructure within our lifetimes, and that’s one of the few things I’m excited about for the near future. It’s unfortunate that it’s taking a crisis to force these changes, but it would be a great pivot nonetheless.

      • skillissuer
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        4 months ago

        i think that in order for that to happen we have to change the way we think about energy. more of use it when it’s available, and less use it on demand

        • MrVilliam@lemmy.world
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          4 months ago

          Dirty production initiates based on demand. So-called “peaker plants” start up under high demand when cost per megawatt rises. They typically start early in the day as most people wake up and cook breakfast and get ready for work and then shut down after people get home and wind down for bed. More extreme versions of this only fire up for more extreme weather events or when other plants trip offline unexpectedly. If demand is normalized, so too is production, which would phase out dirtier power production like coal and natural gas. As an operator at a combined cycle natural gas power plant, this would force me to find a new job. Which is fine by me. The system needs to be changed to be fixed, even if it causes a little pain for me.

          Think of the grid as a pressurized system. To maintain consistent pressure, demand and supply need to be approximately equivalent. When use is high, the pressure drops so demand goes up to maintain that pressure, so prices per megawatt rise to incentivize power plants to step on the gas pedal to produce more. When use drops off, that production needs to reduce to prevent over pressurization of the grid. With battery storage, that pressure swing diminishes. It’s effectively a pressure regulator.

          Additionally, the home power management system via UPS and inverters does exactly what you’re saying in terms of using it when it’s available. At times of high demand and high cost and low supply, your home could seamlessly switch over to your home battery supply for your energy needs to remove strain on the grid, and this would be attractive to set up through things like proposed tax credits and generally reducing your home energy bill. So at 3pm in an August heat wave, your AC could be battery powered from when you charged while you slept the night before. And you’ll recharge tonight when everybody’s AC has switched off for the most part. All this to say: you’re absolutely right and we already agree, but also we can use emerging tech and legislation to vastly expedite this badly-needed transition.

    • CheeseNoodle@lemmy.world
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      4 months ago

      Sodium batteries are already being produced (only in one factory in the US and one in China so far but its a start to commercial production), there’s enough of that stuff to build batteries for the entire planet a thousand times over.

    • ✺roguetrick✺@lemmy.world
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      4 months ago

      Oh there’s enough lithium. Not enough lithium production, surely, but there’s enough lithium in the ocean and in brines easily.

    • cygnus@lemmy.ca
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      4 months ago

      there’s not enough lithium on this planet to store enough energy for like half of europe nevermind entire world

      This is a good use case for sodium batteries. They’re less energy-dense so not great for vehicles, but for a stationary application like this they’re perfect.

      • skillissuer
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        4 months ago

        yeah this is fine, but these need to run at high temperatures last time i’ve checked. that makes it a bit more complicated to use

        • ProdigalFrog@slrpnk.net
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          4 months ago

          Sodium electric batteries, like the type that CATL developed? Or do you mean hot molten salt thermal batteries? Because I think the other poster is referring to the first kind.

          • skillissuer
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            4 months ago

            i thought sodium batteries need low hundreds C for ceramic electrolyte to work. i stand corrected

            e: CATL made sodium-ion battery, i was thinking of sodium-sulfur battery

    • Addv4@lemmy.world
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      4 months ago

      There are plenty of alternatives for lithium batteries, chiefly sodium and a redox flow. Heating/cooling is good as well to store, but not every structure is energy efficient enough that it would make much sense. Good thing to work towards, but grid batteries would probably be faster and easier to implement. I have reservations towards pumped hydropower, in part due to watching how hard it is to decommission a lot of hydroelectric dams these days in US as well as the cost to create the areas to hold the water (a lot of the areas that are geographically advantageous for pumped hydropower tend to be nature reserves or national parks, soo…).

      • Semi-Hemi-Lemmygod@lemmy.world
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        4 months ago

        Since most energy is used for heat, storing it as heat makes a lot of sense, and there are sand thermal storage systems that can scale from single household to whole neighborhoods.

        • Addv4@lemmy.world
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          4 months ago

          But then you’re just having another system for storing energy, which probably isn’t very easy to implement. An easier solution if you don’t want to use grid batteries is just to improve housing insulation and schedule heating/cooling for non peak hours, so that you are just using less energy overall. The problem in my mind is that that would require a lot of renovation on older homes, which is just more expensive and slower than adding grid batteries. Don’t get me wrong, those changes should be mandated for newer housing, but expecting it to be implemented in older housing probably isn’t gonna happen.

          • Semi-Hemi-Lemmygod@lemmy.world
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            4 months ago

            They’re already using them in Finland. And there’s a company building them for residential applications

            If you take something not unlike a water heater and fill it with sand that you then heat to about 1,000 degrees farenheit. Then when you need heat you just pump some air through it and use that feed of hot air to provide heat where you need it. And unlike heat pumps, this can be added to the sort of baseboard heat you find in a lot of older homes.

            And since the heaters are just simple resistive coils with 100% efficiency, it’s a simple and cheap way to store electricity that you’re going to use for heating anyway. Remember that every time you change energy from one kind to another you’re going to lose some of it in the process.

      • skillissuer
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        4 months ago

        i have a sneaking suspicion that if 80%+ of energy is used on heating anyway then storing that heat at point of use and topping it up when excess energy is available is the easiest, least wasteful way to go

        • Addv4@lemmy.world
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          4 months ago

          Heating/cooling probably, but renovation of older structures is generally expensive and complicated, whereas grid batteries can scale until newer construction (which should be more insulated) can keep up. It’s not an either or, but more of both that will compliment each other as time progresses.

      • skillissuer
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        4 months ago

        redox flow doesn’t have that much better energy density. granted, it’s great for long term storage, but it’s still not there, plus it takes stupidly large amounts of vanadium to run. there’s also zinc bromide flow battery but this one deposits zinc so it’s limited on one side

    • SeaJ@lemm.eeOP
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      4 months ago

      You know what pumped storage hydro is? A battery. Unfortunately that is not an option everywhere and takes up a massive amount of space. The space portion is not a huge issue for grid energy storage for the most part but it can definitely limit where you can do it and its capacity.

      As for the amount of lithium available, there is absolutely more than enough considering it is one of the most abundant materials on our planet. Not that we need to use lithium for grid energy storage. Lithium is very high density energy storage which you are correct that is not a high priority for grid energy storage.

      Basically there is no one solution for grid energy storage. There are mechanical batteries, medium density chemical batteries, and even “depleted” EV batteries. We just need to apply what is right for each particular scenario.

      I’m not disagreeing with you overall. But I figured more info and context is helpful.

    • thebestaquaman@lemmy.world
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      4 months ago

      Of course, Li-ion batteries will never cover large-scale power demand. Not primarily because of lack of lithium, but because it’s a technology that scales far too poorly into the MWh/TWh scale, and has a far too short lifetime.

      The battery tech we need for truly large scale storage is different from what we need for small, portable storage. Stuff like redox-flow batteries are looking promising.

      There’s also hydrogen, with different storage methods being actively researched- from direct storage to using ammonia as a carrier.

      The issue with using mechanical storage (like pumped hydropower) is threefold (off the top of my head):

      1. It has ridiculously low energy density
      2. Even after > 100 years of pumps and turbines, the power loss in a pump/release cycle is very high.
      3. It’s heavily limited by geography

      I’m not saying pumped hydropower isn’t part of the solution: I believe the solution is that we need many solutions. I just think it’s important to point out that battery tech isn’t some monolithic thing, and that there are issues with pumped hydropower (and mechanical storage in general).