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1. Enhanced photoresponse in BaZrS3 thin films via sputtering and flux-assisted sulfurization

   https://doi.org/10.1557/s43578-025-01679-4  

   Hui, Haolei; Samson, Lauren; Ullah, Arif; Wang, Chenyu; Schoener, Brandon; Seo, Jung-Hun; Cerne, John; Markelz, Andrea; Sun, Yi-Yang; Zhang, Shengbai; et al (September 2025, Journal of Materials Research)

   Abstract Chalcogenide perovskites, particularly BaZrS₃, hold promise for optoelectronic devices owing to their exceptional light absorption and inherent stability. However, thin films obtained at lower processing temperatures typically result in small grain sizes and inferior transport properties. Here we introduce an approach employing co-sputtering elemental Ba and Zr targets followed by CS₂sulfurization, with a judiciously applied NaF capping layer. NaF acts as a flux agent during sulfurization, leading to marked increase in grain size and improved crystallinity. This process results in near-stoichiometric films with enhanced photoresponse. Terahertz spectroscopy further reveals a carrier mobility more than two orders of magnitude higher than those obtained from field-effect transistor measurements, suggesting that bulk transport is limited by grain boundary scattering. Our results demonstrate flux-assisted sulfurization as an effective strategy to improve the crystallinity of chalcogenide perovskite thin films for optoelectronic applications. Graphical abstract 

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2. A Processing Route to Chalcogenide Perovskites Alloys with Tunable Band Gap via Anion Exchange

   https://doi.org/10.1002/adfm.202405135  

   Ye, Kevin; Sadeghi, Ida; Xu, Michael; Van_Sambeek, Jack; Cai, Tao; Dong, Jessica; Kothari, Rishabh; LeBeau, James M; Jaramillo, R (May 2024, Advanced Functional Materials)

   Abstract The synthesis of BaZr(S,Se)₃chalcogenide perovskite alloys is demonstrated by selenization of BaZrS₃thin films. The anion‐exchange process produces films with tunable composition and band gap without changing the orthorhombic perovskite crystal structure or the film microstructure. The direct band gap is tunable between 1.5 and 1.9 eV. The alloy films made in this way feature one‐hundred‐times stronger photoconductive response and a lower density of extended defects, compared to alloy films made by direct growth. The perovskite structure is stable in high‐selenium‐content thin films with and without epitaxy. The manufacturing‐compatible process of selenization in H₂Se gas may spur the development of chalcogenide perovskite solar cell technology. 

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3. The Synergetic Ionic and Electronic Features of MAPbI₃ Perovskite Films Revealed by Electrochemical Impedance Spectroscopy

   https://doi.org/10.1002/adom.202301677  

   Jha, Sauraj; Haroldson, Ross; Zakhidov, Anvar A.; Slinker, Jason D. (November 2023, Advanced Optical Materials)

   Abstract Perovskites have emerged as a forerunner of electronics research due to their vast potential for optoelectronic applications. The numerous combinations of constituent ions and the potential for doping of perovskites lead to a high demand to track the underlying electronic properties. Solution‐based electrochemistry is particularly promising for detailed and facile assessment of perovskites. Here, electrochemical impedance spectroscopy (EIS) of methylammonium lead iodide (MAPbI₃) thin films is performed and model them with an equivalent circuit that accounts for solvent, ionic, and thin film effects. A dielectric constant consistent with prior AC studies and a diffusion constant harmonious with cation motion in MAPbI₃are extracted. An electrical double layer thickness in the perovskite film of 54 nm is obtained, consistent with lithium doping in perovskite films. Comparing the EIS and equivalent circuit model of perovskite films to control ITO‐only data enabled the assignment of the ions at each interface. This comparison implied a double layer of primarily lithium ions inside the perovskite film at the solution interface with significant recombination of ions on the solution side of the interface. This demonstrates EIS as a powerful tool for studying the fundamental charge accumulation and transport processes in perovskite thin films. 

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4. Relative water stability of powder vs. thin films of organic–inorganic halide perovskites including durability of a thin film bis(thiophenyl)-pyrrole lead iodide

   https://doi.org/10.1039/D5MA00617A  

   Naveed, Abdul Basit; Mulvehill, Matthew C; Javaid, Aftab; Grapperhaus, Craig A; Spurgeon, Joshua M (November 2025, Materials Advances)

   Organic-inorganic halide perovskites are promising semiconductors for energy-conversion applications, but these materials face an inherent limitation due to poor intrinsic stability, particularly via decomposition upon exposure to water. The dimensionality and stability of perovskite materials are highly dependent on the organic cation in the perovskite. The incorporation of bulky organic ligands in the structure induces 2D layered perovskites where organic ligands are perpendicular to the inorganic layers and can enhance the perovskite moisture stability through the ligand hydrophobicity. Herein, the relative water stability of reportedly water-stable organic-inorganic halide perovskites were compared between microparticulate powders and compact thin films. In particular, the 3D perovskite DMASnBr3 (DMA = dimethylammonium) and 2D perovskite (PEA)2SnBr4 (PEA = phenylethylammonium) were synthesized in both forms and characterized for water stability. The microparticulate crystals of both materials exhibited significant stability in water while analogous thin films were highly unstable, which was attributed to the presence of a soluble intermixed phase. A new bulky organic ligand, 8-(2,5-bis(thiophen-2-yl)-1H-pyrrol-1-yl)-octylammonium (2TPO), with hydrophobic wing-like groups to help impede water ingress was synthesized and incorporated into a 2D perovskite structure. A thin film of (2TPO)2PbI4 exhibited strongly enhanced durability when fully immersed in water for several minutes or exposed to 85% relative humidity for several days. Material stability was characterized using techniques such as X-ray diffraction (XRD), UV-visible spectroscopy, and X-ray photoelectron spectroscopy (XPS). 

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5. Eco-friendly synthesis and stability analysis of CsPbBr ₃ and poly(methyl methacrylate)-CsPbBr ₃ films

   https://doi.org/10.1088/1361-6528/adbbf6  

   Huang, You-Lin; Li, Wei; Yang, Fuqian (March 2025, Nanotechnology)

   Abstract This study presents an eco-friendly mechanochemical synthesis of cesium lead bromide (CsPbBr₃), eliminating the need of organic solvents and high temperatures. The synthesized CsPbBr₃powder is used to fabricate poly(methyl methacrylate) (PMMA)-CsPbBr₃films and CsPbBr₃nanocrystals (NCs). The photoluminescence (PL) peaks of the emission light are centered at 541 nm, 538 nm, and 514 nm for the CsPbBr₃powder, PMMA-CsPbBr₃films, and CsPbBr₃NCs, respectively, correlating with crystal sizes of 0.96, 0.56, and 0.12μm, respectively. The PL lifetime analysis reveals decay times ( ${\tau }_1,{\tau }_2$) of (4.18, 20.08), (5.7, 46.99), and (5.81, 23.14) in the units (ns, ns) for the CsPbBr₃powder, PMMA-CsPbBr₃films, and CsPbBr₃NCs, respectively. The PL quantum yield of the CsPbBr₃NCs in toluene is 61.3%. Thermal activation energies for thermal quenching are 217.48 meV (films) and 178.15 meV (powder), indicating improved thermal stability with the PMMA encapsulation. The analysis of the PL intensity decay from water diffusion in the PMMA-CsPbBr₃films yields 1.70 × 10⁻¹²m²s⁻¹for the diffusion coefficient of water, comparable to that for water diffusion in pure PMMA. This work demonstrates a scalable, sustainable strategy for CsPbBr₃synthesis and stability enhancement for optoelectronic applications. 

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