Queen Mary University of London researchers have developed a new process for producing stable perovskite materials to create more efficient solar cells.

Currently crystalline silicon is the most widely used material for solar cells. However, over the last decade, perovskite solar cells, made from metal halide perovskite materials, have shown promise to make cheaper, and potentially more efficient solar cells than silicon.

Now perovskite solar cells can now compete in terms of efficiency with more established silicon based solar cells, but a key challenge that remains unaddressed is their chemical instability. Perovskite materials are very sensitive to moisture, oxygen and even light, meaning they can degrade rapidly in air.

One perovskite material, formamidinium perovskite, could help to solve this issue as its pure, black- colored crystal structure, known as FAPbI3, is more chemically stable than many other perovskites. Its optical properties are also much better suited to absorb light and produce electricity efficiently in a solar cell than existing perovskite materials.

However, creating this black, stable form of the material is difficult, because it can often form a yellow phase that isn’t suitable for solar cells.

In the QMUL study, published in the journal Advanced Materials, researchers describe a new process for creating FAPbI3.

One of the challenges with making FAPbI3 is that the high temperatures (150°C) used can cause the crystals within the material to ‘stretch’, making them strained, which favors the yellow phase. And while some previous reports have used small amounts of additional chemicals, or ‘additives’ to help form FAPbI3 under these conditions, it can be very hard to control the uniformity and amounts of these additives when making solar cells at a very large scale, and the long-term impact of including them is not yet known.

Photographs showing the color change of FAPbI3 film after exposure to solvent aerosol flow (0 then 14 seconds) in a chemical vapor deposition chamber. The cylindrical tube for aerosol assisted chemical vapor deposition and the direction of aerosol flow are indicated by arrows in the photo of 0s; the heating graphite block and inlet of aerosol are labeled on the same photograph. The arrows on photograph of 14 seconds points to the FAPbI3 film. Image Credit: Queen Mary University of London. Click image for the largest view.

Instead, the novel approach described in the study exposes films of FAPbI3 to an aerosol containing a mixture of solvents at a lower temperature (100°C). The researchers found that they could form very stable black-phase FAPbI3 after just one minute, in comparison to other approaches that can take around 20 minutes. They also show that the lower temperatures used help to ‘relax’ the crystals within the material.

Dr. Joe Briscoe, Reader in Energy Materials and Devices at Queen Mary, said, “Pure formamidinium perovskite could produce perovskite solar cells that are more efficient and stable that those made with other commonly used hybrid perovskites based on methylammonium. This could be really important for commercializing this technology, particularly as the process can easily be scaled up.”

“In this study, we’ve demonstrated a novel, more efficient approach to create pure and stable black formamidinium perovskite FAPbI3. As our process uses an ‘inverted’ perovskite solar cell structure and lower annealing temperature, this also makes it very suitable for making flexible solar cells on plastic, which could have a lot of applications for example in clothing and vehicles,” explained Dr. Briscoe.


For solar enthusiasts this is great news indeed. Likely cutting costs and extending the range of uses are both quite the achievements. One surely hopes that commercialization can scale up without any roadblocks or expensive engineering. And keep in mind this is just the first iteration of this new path for perovskite technology.


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