• ArtikBanana@lemmy.dbzer0.comOP
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    3 months ago

    One of the main advantages here is that this can be applied to almost any surface because of how thin it is.

    From the article:

    We can envisage perovskite coatings being applied to broader types of surfaces to generate cheap solar power, such as the roofs of cars and buildings and even the backs of mobile phones. If more solar energy can be generated in this way, we can foresee less need in the longer term to use silicon panels or build more and more solar farms.

    • Bookmeat@lemmy.world
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      3 months ago

      Back of a cell phone won’t work because people put those into bulky cases.

      • Nutteman@lemmy.world
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        3 months ago

        Dang, too bad there aren’t insanely smart engineers who have figured out how to make your little hand rectangle go brrrrr to figure out a way to make it work.

      • shortwavesurfer@lemmy.zip
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        3 months ago

        So put it on the case with one of those wireless charging coils in the case, or at absolute worst, a tiny, tiny connector that plugs into your USB-C port

    • jordanlund@lemmy.world
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      3 months ago

      But if you have to stack the layers to get the 27% efficiency then it’s no longer thin. :)

      • ArtikBanana@lemmy.dbzer0.comOP
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        3 months ago

        It might not be as thin as before, but is several microns of thickness not thin?
        It was nice if they gave more details about exactly how thick it is at 27% efficiency though.
        I’ll look around to see if I can find more information about it.

        Edit: And by the way, I’m actually not aware of any 27% solar panels currently in production.
        Other than the ones Ofxord PV has recently begun manufacturing (established by the same Prof. leading this research).

        • jordanlund@lemmy.world
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          3 months ago

          Just quoting the article:

          “from around 6% to over 27%, close to the limits of what single-layer photovoltaics can achieve today.”

          But I guess it depends too on how many layers we’re talking about which isn’t specified.

          • TheGrandNagus@lemmy.world
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            3 months ago

            You’re misrepresenting what they say:

            During just five years of experimenting with our stacking or multi-junction approach, we have raised power conversion efficiency from around 6% to over 27%, close to the limits of what single-layer photovoltaics can achieve today.

            We believe that, over time, this approach could enable the photovoltaic devices to achieve far greater efficiencies, exceeding 45%.

            “6% to over 27%” isn’t the range of what they can achieve now. 6% efficiency was where the technology was at 5 years ago, and now they get 27%.