Technology research and market intelligence company IDTechEx has explored the perovskite PV market, forecasting that annual perovskite PV revenue will reach almost US$12 billion by 2035.

IDTechEx also sees perovskite/silicon tandem solar panels as "the most significant opportunity for this sector" and "are overall anticipated to dominate the perovskite PV market". Their similar mechanical properties to single-junction silicon solar, whilst achieving higher PCEs, makes them particularly suited for traditional solar applications, including solar farms and rooftop application. 

Hybrid perovskites show piezoelectric properties due to polarization and centro-symmetry breaking of PbX₆ pyramids (X = I^-, Br^-, Cl^-). Researchers from The Hebrew University of Jerusalem, Polish Academy of Sciences and Nanyang Technological University recently examined the piezoelectric response of quasi-2D perovskites using various barrier molecules: benzyl amine (BzA), phenylethyl amine (PEA), and butyl diamine (BuDA).

Utilizing piezoelectric force microscopy measurements, the team determined the piezoelectric coefficient (d33) where BuDA exhibits a substantial response with values of 147 pm V^–1 for n = 5, better than the other quasi-2D and 3D perovskite counterparts. Density functional theory calculations revealed distorted bond angles in the PbBr₆ pyramids for quasi-2D perovskites, enhancing symmetry breaking. 

Researchers from China's Xi’an Jiaotong University, Huazhong University of Science and Technology, Fudan University, ULVAC-PHI Instruments, National University of Singapore (NUS), Sweden's Uppsala University and EPFL have developed a self-assembled bilayer (SAB) that can be used as a hole contact material that grants improved adhesive contact with the perovskite film. 

A schematic illustration of the inverted PSCs. Image from: Nature Energy

The team went on to fabricate an inverted perovskite solar cell that utilizes the self-assembled bilayer (SAB) as a hole-selective molecular contact. The cell was made with a substrate made of glass and transparent conductive oxides (TCOs), the proposed bilayer, the perovskite absorber, an ETL based on buckminsterfullerene (C60), a bathocuproine (BCP) buffer layer, and a silver (Ag) metal contact. 

Researchers from EPFL and CSEM recently fabricated efficient (>20 %) and stable (T80 ∼ 720 h) planar FAPbI₃-based perovskite (1.54 eV) solar cells via a hybrid evaporation-spin coating process. 

FAPbI₃-based perovskite films were fabricated via a hybrid two-step evaporation-spin coating method in an inverted (p-i-n) configuration, and the effects of optimized parameters on the film growth and devices’ performances were investigated. Transferring these films into tandem devices atop single-side textured silicon heterojunction bottom cells, the team obtained an efficiency of >24 % under AM1.5 G illumination for monofacial devices with an active area of 1.21 cm². Furthermore, the bifacial devices generated >27 mW cm⁻² power output with 15 % rear illumination fraction.

Mellow Energy has announced the launch of what it refers to as "the world’s largest integrated flexible perovskite photovoltaic (PV) module" from its 100MW-scale production line. The module measures 1.2×1.6 square meters and weighs approximately 2.04 kilograms.

According to Mellow Energy, tests conducted by TÜV Rheinland, an internationally renowned testing and certification body, have confirmed that the 1.2×1.6-square-meter double-glass module achieves a full-area efficiency of 17.9% under standard testing conditions.

Monolithic all-perovskite tandem solar cells present a promising approach for exceeding the efficiency limit of single-junction solar cells. However, the substantial open-circuit voltage loss in the wide-bandgap perovskite subcell hinders further improvements in power-conversion efficiency. Now, researchers from China's Nanjing University, Renshine Solar (Suzhou) and Ecole Polytechnique Fédérale de Lausanne (EPFL) have developed wide-bandgap perovskite films with improved crystal orientation that suppress non-radiative recombination. 

The team showed that using two-dimensional perovskite as an intermediate phase on the film surface promotes heterogeneous nucleation along the three-dimensional perovskite facets during crystallization. Preferred orientations can be realized by augmenting the quantity of two-dimensional phases through surface composition engineering, without the need for excessive two-dimensional ligands that otherwise impede carrier transport. 

Increasing module efficiency and expanding manufacturing capacity play complementary roles in reducing costs of metal halide perovskite/silicon tandem solar modules, according to researchers at the U.S. Department of Energy's National Renewable Energy Laboratory (NREL). Each cost lever can play a similar role depending on a manufacturer’s ability to scale up and improve module performance.

They explain that tandem PV technology, created by pairing silicon with metal halide perovskites (MHPs) for example, can help create a solar module that can convert more sunlight to electricity than using silicon alone. This tandem technology is still in the early stages, and there are multiple options being pursued to integrate MHPs and silicon, with a lot of unknowns in terms of cost and performance. To address this gap, the researchers built a manufacturing cost model that combines laboratory processes with existing equipment and supply chains to compare different possible approaches at scale.

Researchers from Northwestern University, Arizona State University, University of Toronto and National University of Singapore have addressed the issue of ion migration, which deteriorates the performance and stability of perovskite solar cells (PSCs). The team has developed a new method to improve the stability and efficiency of PSCs through surface functionalization, which uses a chemical compound called 5-ammonium valeric acid iodide (5-AVAI) to enable the uniform growth of aluminum oxide (Al₂O₃) through atomic layer deposition. This process creates a robust barrier that suppresses halide migration by more than an order of magnitude.

Using this method, the researchers tested solar cells, and found that they retained 90% of their initial power conversion efficiency (PCE) after 1,000 hours of continuous operation at 55 degrees Celsius under full sunlight, compared to less than 200 hours without the barrier layer. 

Researchers from Pakistan's University of Engineering & Technology (UET) and National University of Technology have reported the use of manual screen printing to fabricate semi-transparent, scalable perovskite solar modules without the requirement for numerous laser-scribing steps. 

A carbon-based, hole-transport-layer-free perovskite solar module with a power conversion efficiency of 11.83% was manufactured, with an active area of 900 cm². Accelerated testing was done in settings with elevated humidity, high sun irradiation, and harsh temperatures to determine whether these modules are ready for the market. 

A new Swansea University-led project has been awarded £3 million to develop and manufacture sustainable perovskite solar modules (PSMs) in Africa, empowering local communities and promoting sustainable energy.

REACH-PSM (Resilient Renewable Energy Access Through Community-Driven Holistic Development in Perovskite Solar Module Manufacturing) aims to establish the continent’s first full-scale demonstration of next-generation solar manufacturing. Funded by the UKRI Ayrton Challenge Programme, REACH-PSM is a collaboration with universities, businesses, and local communities in Nigeria, Rwanda, Kenya, and South Africa.