Locking in Solar Power: How a Stronger Interlayer Boosts Perovskite Cell Durability
New Molecular Designs Extend the Life and Efficiency of Next-Generation Solar Cells
Posted on the RASEI website with permission and minor modifications from the piece published by David DeFusco on the .听
听
A new study published in听Science led by researchers at UNC-Chapel Hill, with collaborators from the Renewable and Sustainable Energy Institute (RASEI), explains why perovskite solar cells鈥攆ast-rising rivals to traditional silicon panels鈥攖end to break down under prolonged heat and sunlight, especially ultraviolet light, and reveals a promising strategy to dramatically slow that damage.
The work focuses on a thin 鈥渋nterlayer鈥 that sits between the electrode and the perovskite material inside a solar cell. This layer is only a single molecule thick, but it plays an outsized role in how long the device lasts.
鈥淭hese interlayers are meant to help charges move efficiently out of the perovskite and into the circuit,鈥 said Chengbin Fei, first author of the study and a postdoctoral researcher in UNC鈥檚 Department of Applied Physical Sciences. 鈥淏ut we found that some of the same chemical features that make them useful can also cause long-term damage if they鈥檙e not tightly attached to the electrode.鈥
Many high-performance perovskite solar cells use interlayers based on phosphonic acids. These molecules stick to a transparent electrode made of indium tin oxide, or ITO, and help pull positive charges out of the perovskite. Until now, most researchers assumed these layers were harmless once installed. Fei and his colleagues discovered that this is not always true.
The researchers found that some of these tiny helper molecules aren鈥檛 firmly stuck to the solar cell鈥檚 surface. When the cell gets hot or sits in sunlight that includes ultraviolet rays, those that are loosely attached molecules can break free. Once that happens, they start interfering with the solar material itself. They trigger harmful changes inside the cell: key ingredients fall apart, iodine-related components react in damaging ways and lead turns into a form that no longer works properly. Over time, all of this damage adds up and causes the solar cell to produce less and less electricity.
鈥淚n simple terms, the acid part of these molecules can act like a slow poison,鈥 said Fei. 鈥淎t high temperatures and under UV light, it accelerates chemical reactions that the perovskite just can鈥檛 tolerate.鈥
To understand what was happening, the researchers used a range of techniques, including spectroscopy and X-ray measurements, to watch how the materials changed over time. They found that stronger acids caused faster damage and that UV light made the reactions much worse. This explained why devices that look stable at first can fail after hundreds or thousands of hours outdoors.
The key advance came when the researchers at UNC and the 麻豆免费版下载 created a new version of this thin helper layer containing a combination of two molecules that sticks much more tightly to the electrode surface. Seth Marder, the senior author at the University of Colorado-Boulder and Director of the Renewable and Sustainable Energy Institute (RASEI) says 鈥渢he molecule our team developed was designed to not only interact with the electrode surface but more strongly with its neighboring molecules. Consequently the molecules stay more securely in place, reducing the reactive parts that can break away and damage the solar material that is deposited on top 鈥. As a result, the layer still helps charges flow out of the cell, but it no longer triggers the damaging reactions that shorten the cell鈥檚 lifetime.
Simply put, 鈥渨hen the molecule is firmly locked onto the surface, it can鈥檛 wander into the perovskite and cause trouble,鈥 said Fei. 鈥淭hat simple change makes a huge difference over time.鈥
Solar cells made with the new interlayer design showed striking improvements and met a key performance milestone. Under harsh test conditions鈥85 degrees Celsius, continuous bright light that included UV and constant operation鈥攖he devices ran for nearly 3,000 hours before losing just 10 percent of their efficiency. That level of durability has not been reported before for this type of perovskite solar cell.
The molecule our team developed was designed to not only interact with the electrode surface but more strongly with its neighboring molecules. Consequently the molecules stay more securely in place, reducing the reactive parts that can break away and damage the solar material that is deposited on top.
- Seth Marder
The researchers also scaled up their approach to small solar modules, closer to what might be used in real products. These 鈥渕inimodules,鈥 about the size of a postcard, reached power conversion efficiencies above 22 percent and kept working for more than 2,000 hours under the same stressful conditions, which is considered very high performance for this type of solar technology.
Jinsong Huang, senior author of the paper and UNC Louis D. Rubin Distinguished Professor, said the results address one of the most important barriers to commercialization. 鈥淓fficiency alone is not enough,鈥 he said. 鈥淔or perovskite solar technology to succeed outside the lab, it must survive heat, light and time. This work shows a clear chemical pathway to make that happen.鈥
Beyond improving one specific material, the study sends a broader message to the field. Tiny details at buried interfaces鈥攑laces that are hard to see and easy to overlook鈥攃an control the lifetime of an entire solar module. By understanding and managing these details, researchers can design devices that last far longer.
鈥淭his study reminds us that stability is a chemistry problem as much as an engineering one,鈥 said Wei You, a co-author of the study and UNC Cary C. Boshamer Distinguished Professor of Chemistry and Applied Physical Sciences. 鈥淥nce you understand the chemistry, you can start to fix it.鈥