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Transparent solar cells for windows

New type of solar cells with 30-year lifetimes

06.10.2021 - High-efficiency but fragile molecules for converting light to electricity thrive with a little protection.

A new transparency-friendly solar cell design could marry high efficiencies with 30-year estimated lifetimes, research led by the University of Michigan has shown. It may pave the way for windows that also provide solar power. “Solar energy is about the cheapest form of energy that mankind has ever produced since the industrial revo­lution,” said Stephen Forrest, who led the research. “With these devices used on windows, your building becomes a power plant.”

While silicon remains king for solar panel efficiency, it isn't transparent. For window-friendly solar panels, researchers have been exploring organic materials. The challenge for Forrest's team was how to prevent very efficient organic light-converting materials from degrading quickly during use. The strength and the weakness of these materials lie in the molecules that transfer the photo­generated electrons to the electrodes, the entrance points to the circuit that either uses or stores the solar power. These non-fullerene acceptors set them apart from the more robust but less efficient fullerene acceptors made of nanoscale carbon mesh. Solar cells made with non-fullerene acceptors that incor­porate sulfur can achieve silicon-rivaling effi­ciencies of 18 %, but they do not last as long.

The team, including researchers at North Carolina State University and Tianjin University and Zhejiang University in China, set out to change that. In their experiments, they showed that without protecting the sunlight-con­verting material, the effi­ciency fell to less than 40 % of its initial value within 12 weeks under the equivalent of 1 sun's illumination. “Non-fullerene acceptors cause very high effi­ciency, but contain weak bonds that easily disso­ciate under high energy photons, especially the UV photons common in sunlight,” said Yongxi Li, U-M assistant research scientist in electrical engineering and computer science.

By studying the nature of the degra­dation in those unprotected solar cells, the team recognized that they only needed shoring up in a few places. First, they'd need to block out that UV light. For that, they added a layer of zinc oxide on the sun-facing side of the glass. A thinner zinc oxide layer next to the light absorbing region helps conduct the solar-generated electrons to the electrode. Unfor­tunately, it also breaks down the fragile light absorber, so the team added a layer of a carbon-based material called IC-SAM as a buffer. 

In addition, the electrode that draws posi­tively-charged holes into the circuit can also react with the light absorber. To protect that flank, they added another buffer layer, this one a fullerene shaped like a soccer ball. The team then tested their new defenses under different inten­sities of simulated sunlight, from the typical 1 sun up to the light of 27 suns, and tempera­tures up to 150 degrees Fahrenheit. By studying how the performance degraded under these condi­tions, the team extra­polated that the solar cells would still be running at 80 % efficiency after 30 years. 

Forrest sees a future of these devices “coming to a window near you.” His team has already increased the trans­parency of the module to 40 %. They believe they can approach 60 % transparency. They're also working on bumping up the efficiency from the 10 % achieved in the reported semi­transparent modules, closer to the 15 % believed to be possible at high trans­parency. Because the materials can be prepared as liquids, the manu­facturing costs are expected to be relatively low. (Source: U. Michigan)

Reference: Y. Li et al.: Non-fullerene acceptor organic photovoltaics with intrinsic operational lifetimes over 30 years, Nat. Commun. 12, 5419 (2021); DOI: 10.1038/s41467-021-25718-w

Link: Optoelectronic Components & Materials Group, Dept. of Electrical Engineering, Material Science and Engineering, University of Michigan, Ann Arbor, USA

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Digital tools or software can ease your life as a photonics professional by either helping you with your system design or during the manufacturing process or when purchasing components. Check out our compilation:

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