'Molecular glue' offers reliable way to improve perovskite solar cells

A research team from Brown University has taken a major step toward improving the long-term reliability of perovskite solar cells, an emerging clean energy technology. In a paper in Science, the team reports the development of a 'molecular glue' that can keep a key interface inside perovskite solar cells from degrading. This treatment dramatically increases the cells' stability and reliability over time, while also improving the efficiency with which they convert sunlight into electricity.

"There have been great strides in increasing the power-conversion efficiency of perovskite solar cells," said Nitin Padture, a professor of engineering at Brown University and senior author of the paper. "But the final hurdle to be cleared before the technology can be widely available is reliability – making cells that maintain their performance over time. That's one of the things my research group has been working on, and we're happy to report some important progress."

Perovskites are a class of materials with a particular crystalline atomic structure. A little over a decade ago, researchers showed that certain perovskites are very good at absorbing light, which set off a flood of new research into perovskite solar cells. The efficiency of those cells has increased quickly and now rivals that of traditional silicon cells.

One major advantage of perovskite light absorbers is that they can be made at near room temperature, whereas silicon needs to be grown from a melt at a temperature approaching 2700°F. Perovskite films are also about 400 times thinner than silicon wafers. The relative ease of the manufacturing processes and the use of less material means perovskite cells can potentially be made at a fraction of the cost of silicon cells.

While the efficiency improvements in perovskites have been remarkable, Padture says, making the cells more stable and reliable has remained challenging. Part of the problem has to do with the layering required to make a functioning cell. Each cell contains five or more distinct layers, each performing a different function in the electricity-generation process.

Since these layers are made from different materials, they respond differently to external forces. Also, temperature changes that occur during the manufacturing process and during service can cause some layers to expand or contract more than others. This creates mechanical stresses at the layer interfaces that can cause the layers to decouple. If the interfaces are compromised, the performance of the cell plummets.

The weakest of those interfaces is the one between the perovskite film used to absorb light and the electron transport layer, which keeps current flowing through the cell.

"A chain is only as strong as its weakest link, and we identified this interface as the weakest part of the whole stack, where failure is most likely," said Padture, who directs the Institute for Molecular and Nanoscale Innovation at Brown. "If we can strengthen that, then we can start making real improvements in reliability."

To do that, Padture drew on his experience as a material scientist developing advanced ceramic coatings for aircraft engines and other high-performance applications. He and his colleagues began experimenting with compounds known as self-assembled monolayers (SAMs).

"This is a large class of compounds," Padture said. "When you deposit these on a surface, the molecules assemble themselves in a single layer and stand up like short hairs. By using the right formulation, you can form strong bonds between these compounds and all kinds of different surfaces."

Padture and his team found that a formulation of SAM with silicon atoms on one side and iodine atoms on the other could form strong bonds with both the election transport layer (which is usually made of tin oxide) and the perovskite light-absorbing layer. The team hoped that the bonds formed by these molecules might fortify the layer interface, and they were right.

"When we introduced the SAMs to the interface, we found that it increases the fracture toughness of the interface by about 50%, meaning that any cracks that form at the interface tend not to propagate very far," Padture said. "So in effect, the SAMs become a kind of molecular glue that holds the two layers together."

Testing of solar cell function showed that the SAMs dramatically increased the functional life of the perovskite solar cells. Non-SAM cells prepared for the study retained 80% of their initial efficiency for around 700 hours of lab testing. Meanwhile, the SAM cells were still going strong after 1330 hours of testing. Based on these experiments, the researchers project the 80%-retained-efficiency life of the SAM cells to be about 4000 hours.

"One of the other things we did, which people don't normally do, is we broke open the cells after testing," said Zhenghong Dai, a Brown doctoral student and first author of the paper. "In the control cells without the SAMs, we saw all kinds of damage such as voids and cracks. But with the SAMs, the toughened interfaces looked really good. It was a dramatic improvement that really kind of shocked us."

Importantly, Padture said, the improvement in toughness did not come at the cost of the power-conversion efficiency. In fact, the SAMs actually improved the cells' efficiency by a small amount. That occurred because the SAMs eliminated tiny molecular defects that form when the two layers bond in the absence of SAMs.

"The first rule in improving the mechanical integrity of functional devices is 'do no harm'," Padture said. "So that we could improve reliability without losing efficiency – and even improving efficiency – was a nice surprise."

The SAMs themselves are made from readily available compounds and are easily applied with a dip-coating process at room temperature. So, according to Padture, the addition of SAMs would potentially add little to the production cost.

The researchers plan to build on this success. Now they've fortified the weakest link in the perovskite solar cell stack, they'd like to move onto the next weakest link, then the next and so on until they've fortified the entire stack. This work will involve strengthening not only the interfaces, but also the material layers themselves. Recently, Padture's research group won a $1.5 million grant from the US Department of Energy to expand on their research.

"This is the kind of research that's required in order to make cells that are inexpensive, efficient and perform well for decades," Padture said.

This story is adapted from material from Brown University, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.