Toray Engineering says that it will ship a slot-die coater to a new perovskite PV production line. The shipment is scheduled by the end of 2022, or in early (Q1)2023. The new coater can handle subsrates up to 1 meter In size, which will enable the world's largest size perovskite PV production line. Products to be manufactured on this line will include BIPV and roof mounted panels, with an annual production capacity of 100 MW.

Toray Engineering has been supplying slot-die coaters and many other process and inspection tools worldwide for the display, semiconductor, and LiB industries. Having two solutions available in slot-die coating, which are Roll to Roll (R2R) and sheet-to-sheet, Toray Engineering is the a leader in slot die equipment supply with a sales record of over 1,000 units.

Chinese perovskite solar PV company Wuxi UtmoLight Technology recently achieved 18.2% power conversion efficiency for an in-house developed large-scale perovskite solar module with an area of 756 cm², as reports suggest.

UtmoLight refers to this as a breakthrough in large size perovskite module technology after having reported the same 18.2% efficiency for a smaller size module with 300 cm² dimension in the past. This shows the module can maintain a high conversion efficiency despite the enlargement of the module area. Mass production of this technology is now becoming mature, it added.

Scientists from the University of Warsaw, Poland-based Military University of Technology, CNR Nanotec, the University of Southampton and the University of Iceland have designed a new photonic system with electrically tuned topological features, constructed of perovskites and liquid crystals. The new system can be used to create efficient light sources.

"We noticed that two-dimensional perovskites are very stable at room temperature, have high exciton binding energy and high quantum efficiency", said PhD student Karolina Lempicka-Mirek from the Faculty of Physics at the University of Warsaw, the first author of the publication. The team explained that these special properties can be used in the construction of efficient and unconventional light sources. 

Korean PV company Hanwha Q Cells reportedly aims to mass-produce perovskite-based tandem cells by June 2026.

According to Hanwha Q Cells, its researchers in Germany have collaborated with Helmholtz-Zentrum Berlin, to develop tandem cells using both perovskite and silicon, which is regarded as an intermediary step to developing cells using perovskite only.

Researchers from Zhejiang Energy Group R&D and the Chinese Academy of Sciences (CAS) have reported what they say is "the first monolithic perovskite/silicon tandem featuring an industrially applicable front-side-nanostructured black silicon with a tunnel oxide passivated contact (TOPCon)".

The TOPCon together with the surface reconstruction of black silicon contributes to the high-level surface passivation without sacrificing the broadband light trapping. Additionally, the reconstructed nanotexture significantly facilitates the wetting of perovskite and acts as a nanoconfining scaffold to guide the vertical growth of perovskite.

Researchers from Japan-based National Institute for Materials Science (NIMS) recently developed a durable 1cm² perovskite solar cell capable of generating electricity for more than 1,000 continuous hours at a photoelectric conversion efficiency (i.e., power generation efficiency) of more than 20% in exposure to sunlight.

As this solar cell can be fabricated on the surface of a plastic material at approximately 100°C, this technique could have great potential for developing light, versatile solar cells.

Researchers from Israel's Bar-Ilan University and Weizmann Inst. of Science have measured the effect of humidity on hardness and elastic modulus (E) for two series of lead halide perovskite single crystals. The results indicated the influence of hydrogen (H)-bonding, bond length, and polarization of the ions in lead halide perovskite single crystals.

The team detected an inverse relation between hardness and modulus, which was strengthened with increased humidity. Their findings shed light on the material's distinct structure and properties at the atomic scale. The conclusion of this work was based on the evaluation of outcomes of various nano-indentation techniques that differentiated between surface and bulk E and explored different manifestations of hardness.

University of Freiburg researchers have evaluated how suitable halide-perovskites are for advanced photoelectrochemical battery applications. The recent paper unveiled important findings that could influence the use of organic-inorganic perovskites as multifunctional materials in integrated photoelectrochemical energy harvesting and storage devices.

Importantly, the research has revealed the tendency for 2-(1-cyclohexenyl)ethyl ammonium lead iodide (CHPI) perovskites to dissolve in highly polar electrolytes commonly employed in current lithium-ion batteries. The selection of low polarity electrolytes stabilizes the CHPI electrode material, leading to purely capacitive behaviors in batteries and minimizing lithium-ion intercalation. However, when applying a galvanostatic charge whilst the perovskite electrode material is in contact with electrolyte leads to photo corrosion and CHPI phase dissolution.

Researchers from Helmholtz-Zentrum Berlin (HZB) have demonstrated the scalable fabrication of perovskite/silicon tandem solar cells with optimized bandgap using the slot-die coating method. The team used slot-die coating for an efficient, 1.68 eV wide bandgap triple-halide (3halide) perovskite absorber, (Cs_0.22FA_0.78)Pb(I_0.85Br_0.15)₃ + 5 mol % MAPbCl₃. The team demonstrated that the fabrication route is suitable for tandem solar cells without phase segregation. 

The researchers successfully fabricated a triple-halide perovskite film with top cell optimized bandgaps, high PL quantum yield (PLQY), and improved film quality using the slot-die coating method. They have also efficiently integrated halide perovskites with industrial silicon bottom cells in a tandem architecture, demonstrating the potential of fabricating industrially relevant and scalable perovskite solar cells.

Researchers from Russia's Kazan Federal University have reported on a new method for the fabrication of polypropylene/metal halide perovskites composite in one single step by co-extrusion of the perovskite precursors with polypropylene. Perovskite quantum dots are formed in-situ, and are uniformly distributed in the polymer matrix.

The team said that the material demonstrated high quantum yield and unprecedented stability at ambient conditions. The team further demonstrated that an extruded strand can be used directly as a filament for 3D printing technology. The developed method is simple, has literally no waste, and is unlimitedly scalable. It offers a way to efficiently solve the problem of stability of perovskites, simultaneously involving them into additive manufacturing technologies.