Researchers from the Okinawa Institute of Science and Technology Graduate University (OIST) have found that a protective layer of epoxy resin helps prevent the leakage of pollutants from perovskite solar cells (PSCs). Adding a “self-healing” polymer to the top of a PSC can drastically reduce how much lead it discharges into the environment. This may give a boost to prospects for commercializing the technology.

“Although PSCs are efficient at converting sunlight into electricity at an affordable cost, the fact that they contain lead raises considerable environmental concern,” explains Professor Yabing Qi, head of the Energy Materials and Surface Sciences Unit, who led the study. "While so-called ‘lead-free’ technology is worth exploring, it has not yet achieved efficiency and stability comparable to lead-based approaches. Finding ways of using lead in PSCs while keeping it from leaking into the environment, therefore, is a crucial step for commercialization.”

A team of Russian-Italian researchers is exploring the use of copper iodide (CuI) as a way to improve the stability of perovskite solar cells. The team from Russia-based institutes NUST MISIS and IPCE RAS, and Italy’s University of Rome Tor Vergata, has applied an additional layer of p-type copper iodide semiconductor, made of molecule of methylammonium lead iodine (MAPbI₃), to a perovskite cell for efficient surface passivation.

According to the authors, the MAPbI₃ photoactive layer crystallizes on the surface of a p-type transport layer carrying positive charges and does not demonstrate rapid degradation when exposed to light when accompanied by the release of iodine compounds similar to the used perovskite material. “As we know, under constant illumination and subsequent heating of perovskite solar cells with a photoactive layer of MAPbI₃, free iodine and hydrogen acid are released, which harms the interface between the layers of perovskite and NiO, forming a set of defects and significantly reducing the stability and performance of the device”, said Danila Saranin, researcher at NUST MISIS Laboratory for Advanced Solar Energy.

An international team of clean chemistry researchers, led by Professor Joseph Shapter and Flinders University, has made very thin phosphorene nanosheets for low-temperature perovskite solar cells (PSCs) using the rapid shear stress of the University’s revolutionary vortex fluidic device (VFD). This new nanomaterial made from phosphorus, may turn out to be a key ingredient for more sustainable and efficient next-generation PSCs.

“Silicon is currently the standard for rooftop solar, and other solar panels, but they take a lot of energy to produce them. They are not as sustainable as these newer options,” says adjunct Professor Shapter, now at University of Queensland.

Researchers at the lab of Anders Hagfeldt at EPFL, working with colleagues at the lab of Michael Grätzel, brought real-world conditions into the controlled environment of the lab. Using data from a weather station near Lausanne (Switzerland), they reproduced the real-world temperature and irradiance profiles from specific days during the course of the year, to test PSCs in real-world conditions.

With this approach, the scientists were able to quantify the energy yield of the devices under realistic conditions. “This is what ultimately counts for the real-world application of solar cells," says Dr. Wolfgang Tress from EPFL.

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An international research team led by the University of Houston researchers have tackled a lingering question about how a two-dimensional perovskite crystal composed of cesium, lead and bromine emits a strong green light. Crystals that produce light on the green spectrum are desirable because green light, while valuable in itself, can also be relatively easily converted to other forms that emit blue or red light, making it especially important for optical applications ranging from light-emitting devices to sensitive diagnostic tools.

There was, however, confusion as to how the crystal, CsPB₂Br₅ , produced the green photoluminescence. Several theories emerged, without a definitive answer. Now, the researcher team from the United States, Mexico and China, led by the University of Houston, have reported that they have used sophisticated optical and high-pressure diamond anvil cell techniques to determine not only the mechanism for the light emission but also how to replicate it.