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1. Accessibility and Mechanical Stability of Nanoporous Zinc Oxide and Aluminum Oxide Coatings Synthesized via Infiltration of Polymer Templates

   https://doi.org/10.3390/polym15204088  

   Omotosho, Khalil D.; Lyon, Zachary; Shevchenko, Elena V.; Berman, Diana (October 2023, Polymers)

   The conformal nanoporous inorganic coatings with accessible pores that are stable under applied thermal and mechanical stresses represent an important class of materials used in the design of sensors, optical coatings, and biomedical systems. Here, we synthesize porous AlOx and ZnO coatings by the sequential infiltration synthesis (SIS) of two types of polymers that enable the design of porous conformal coatings—polymers of intrinsic microporosity (PIM) and block co-polymer (BCP) templates. Using quartz crystal microbalance (QCM), we show that alumina precursors infiltrate both polymer templates four times more efficiently than zinc oxide precursors. Using the quartz crystal microbalance (QCM) technique, we provide a comprehensive study on the room temperature accessibility to water and ethanol of pores in block copolymers (BCPs) and porous polymer templates using polystyrene-block-poly-4-vinyl pyridine (PS75-b-P4VP25) and polymers of intrinsic microporosity (PIM-1), polymer templates modified by swelling, and porous inorganic coatings such as AlOx and ZnO synthesized by SIS using such templates. Importantly, we demonstrate that no structural damage occurs in inorganic nanoporous AlOx and ZnO coatings synthesized via infiltration of the polymer templates during the water freezing/melting cycling tests, suggesting excellent mechanical stability of the coatings, even though the hardness of the inorganic nanoporous coating is affected by the polymer and precursor selections. We show that the hardness of the coatings is further improved by their annealing at 900 °C for 1 h, though for all the cases except ZnO obtained using the BCP template, this annealing has a negligible effect on the porosity of the material, as is confirmed by the consistency in the optical characteristics. These findings unravel new potential for the materials being used across various environment and temperature conditions. 

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2. Block Copolymer-Templated Synthesis of Fe–Ni–Co-Modified Nanoporous Alumina Films

   https://doi.org/10.3390/app151910473  

   Ozoude, Chinemerem; Gurung, Vasanta; Omotosho, Khalil D; Shevchenko, Elena V; Berman, Diana (October 2025, Applied Sciences)

   Despite intense interest in the catalytic potential of transition metal oxide heterostructures, originating from their large surface area and tunable chemistry, the fabrication of well-defined multicomponent oxide coatings with controlled architectures remains challenging. Here, we demonstrate a simple and effective swelling-assisted sequential infiltration synthesis (SIS) strategy to fabricate hierarchically porous multicomponent metal-oxide electrocatalysts with tunable bimetallic composition. A combination of solution-based infiltration (SBI) of transition metals, iron (Fe), nickel (Ni), and cobalt (Co), into a block copolymer (PS73-b-P4VP28) template, followed by vapor-phase infiltration of alumina using sequential infiltration synthesis (SIS), was employed to synthesize porous, robust, conformal and transparent multicomponent metal-oxide coatings like Fe/AlOx, Fe+Ni/AlOx, and Fe+Co/AlOx. Electrochemical assessments for the oxygen evolution reaction (OER) in a 0.1 M KOH electrolyte demonstrated that the Fe+Ni/AlOx composite exhibited markedly superior catalytic activity, achieving an impressive onset potential of 1.41 V and a peak current density of 3.29 mA/cm2. This superior activity reflects the well-known synergistic effect of alloying transition metals with a trace of Fe, which facilitates OER kinetics. Overall, our approach offers a versatile and scalable path towards the design of stable and efficient catalysts with tunable nanostructures, opening new possibilities for a wide range of electrochemical energy applications. 

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3. Polycaprolactone - based block copolymers for nanopatterning oxide materials via sequential infiltration synthesis

   https://doi.org/10.1088/1361-6528/ae11bb  

   Patra, Sudarshana; Herbert, Carter; Nichols, Lane; Sarwara, Prachi; Manna, Uttam; Biswas, Mahua (October 2025, Nanotechnology)

   Abstract Sequential infiltration synthesis (SIS) has emerged as a powerful technique to integrate inorganic materials into polymeric templates for fabricating functional hybrid and inorganic-only nanostructures. While several polymers, including self-assembled block copolymers (BCPs), have been widely used as templates for inorganic and hybrid oxide nanostructures, biocompatible polymers such as polycaprolactone (PCL) have not been explored for nanopatterning. In this work, we investigate SIS in polystyrene-block-polycaprolactone (PS-b-PCL) BCPs to demonstrate the feasibility of PCL as a guiding polymer for selective infiltration of Al₂O₃. Fourier transform infrared spectroscopy (FTIR) confirmed the strong interaction of TMA–H₂O precursors with the oxygen-containing functional groups of PCL, while scanning electron microscopy (SEM) revealed well-defined Al₂O₃ nanostructures after SIS and polymer removal. By varying the number of SIS cycles and processing temperatures, we observed systematic changes in the inorganic content and nanostructural fidelity, highlighting the tunability of the process. Notably, significant Al₂O₃ incorporation occurred during the first SIS cycle due to strong PCL–precursor interactions, even at temperatures as low as 60 °C, making the process both cost-effective and precise. These findings demonstrate that PCL is a promising guiding polymer for SIS, with potential to extend beyond conventional systems such as polymethylmethacrylate (PMMA). This work opens new opportunities for fabricating oxide nanostructures with applications in nanopatterning, dielectric coatings, and bio-related nanomaterials. 

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4. Synthesis of Inorganic Hollow Nanospheres and their Application in Drug Delivery

   Guragain, Sudhina (January 2019, Soc)

   Several approaches have been made to synthesize inorganic hollow nanospheres. A dual-template system is the most effective method, usually using surfactants to form mesoporous shells and rigid templates to form interior hollow structures. However, the removal of rigid templates is time consuming and uneconomical. The self-assembly of soft-templates is more convenient and is able to directly construct hollow mesoporous nanoparticles. The soft-templating approach especially the micelles of amphiphilic block copolymers are very helpfulfor creating hollow interiors andporous shell. The hollow void and thickness of shell can be easily tuned by changing either molecular weight of polymer or solution properties. This review focuses on the synthesis of inorganic hollow nanospheres and their application in drug delivery. The large hollow void space with thorough porosity are always beneficial for drug loading and release. 

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5. Templated Synthesis of Copper Nanoclusters with a Hybrid Lysozyme-Polymer Material for Enhanced Fluorescence

   https://doi.org/10.1021/acs.bioconjchem.4c00058  

   Larkin, James O; Cheng, Zhihua; Arefeayne, Yafet; Segatori, Laura; Jones, Matthew R; Ball, Zachary T (May 2024, Bioconjugate Chemistry)

   Hybrid materials that combine organic polymers and biomacromolecules offer unique opportunities for precisely controlling 3D chemical environments. Although biological or organic templates have been separately used to control the growth of inorganic nanoclusters, hybrid structures represent a relatively unexplored approach to tailoring nanocluster properties. Here, we demonstrate that a molecularly defined lysozyme–polymer resin material acts as a structural scaffold for the synthesis of copper nanoclusters (CuNCs) with well controlled size distributions. The resulting CuNCs have significantly enhanced fluorescence compared with syntheses based on polymeric or biological templates alone. The synergistic approach described here is appealing for the synthesis of biocompatible fluorescent labels with improved photostability. 

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