So, the team … got efficiencies in the area of 33 to 34 percent. They also sent a sample to a European test lab, which came out with an efficiency of 33.7 percent. The researchers have a few ideas that should boost this to 35 percent, but didn’t attempt them for this paper. For comparison, the maximum efficiency for silicon alone is in the area of 27 percent, so that represents a very significant boost and is one of the highest perovskite/silicon combinations ever reported.
Love this research and I hope solar eventually beats ICE engines for efficiency.
However…
The crystals were reasonably stable when simply exposed to light. But the combination of light and heat caused a more significant decay in performance. The researchers say that “devices maintain ≥90 percent of their initial performance up to 1,000 hours,” but a decay of up to 10 percent in about three months is not ready for commercial deployment. So, still some work to do there.
Solar still indirectly creates pollution in the form of production of the materials needed, manufacturing, etc. Also, huge solar farms can have a significant detrimental impact on local ecosystems, in addition to the large amount of waste created from old panels:
https://hbr.org/2021/06/the-dark-side-of-solar-power
It’s still better than ICE, as that also creates waste and actively pollutes, but it’s still notable and hopefully over time those negative byproduct can also be eliminated/significantly reduced.
I hope solar eventually beats ICE engines for efficiency
I’m not sure your comment makes a lot of sense. The problem with solar isn’t that it’s not as efficient as internal combustion engines, it’s that you can’t generate electricity on-demand. But it’s already a cheaper form of energy than burning fossil fuels in many countries.
Even conventional solar panels work better when they are cool. Someone smart figured out that you can pump water through them and then use that hot water in your house. You get hot water while making your solar panels more productive. Of course they are crazy expensive.
Given that the first perovskites studied had lifespans that could be measured in minutes, this is great progress, but the fundamental problem is that as a class of materials they just don’t want to exist outside of an inert atmosphere. Without significant progress in stability and encapsulation materials, they’re more of a research curiosity than a viable real-world PV tech.
Love this research and I hope solar eventually beats ICE engines for efficiency.
However…
The differences in efficiency result in very different things.
ICE - heat, smoke, carbon, pollution
Solar -
Solar still indirectly creates pollution in the form of production of the materials needed, manufacturing, etc. Also, huge solar farms can have a significant detrimental impact on local ecosystems, in addition to the large amount of waste created from old panels: https://hbr.org/2021/06/the-dark-side-of-solar-power
https://www.popsci.com/environment/solar-farm-construction-epa-water-violations/
It’s still better than ICE, as that also creates waste and actively pollutes, but it’s still notable and hopefully over time those negative byproduct can also be eliminated/significantly reduced.
Agreed!
However ICE arguments include efficiency so that’ll be one major obstacle hurdled
I’m not sure your comment makes a lot of sense. The problem with solar isn’t that it’s not as efficient as internal combustion engines, it’s that you can’t generate electricity on-demand. But it’s already a cheaper form of energy than burning fossil fuels in many countries.
Even conventional solar panels work better when they are cool. Someone smart figured out that you can pump water through them and then use that hot water in your house. You get hot water while making your solar panels more productive. Of course they are crazy expensive.
Internal combustion engine engines.
Sorry, I forgot to go to ATM machine before I wrote that comment
Do you still remember your PIN number though?
No, but I have a device with a LCD display where I can look it up
Clearly
Given that the first perovskites studied had lifespans that could be measured in minutes, this is great progress, but the fundamental problem is that as a class of materials they just don’t want to exist outside of an inert atmosphere. Without significant progress in stability and encapsulation materials, they’re more of a research curiosity than a viable real-world PV tech.