Journal
MICROPOROUS AND MESOPOROUS MATERIALS
Volume 345, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.micromeso.2022.112246
Keywords
Mesoporous; Thin-film; Mechanical properties; Co-assembly; Scratching; Block copolymers
Categories
Funding
- EPSRC Industrial Case Award [EP/M506448/1]
- Henry Royce Institute
- EPSRC [EP/R00661X/1]
- EPSRC New Investigator Award [EP/R035105/1]
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This study provides a comprehensive investigation into the relationship between the porosity, material processing, and mechanical properties of mesoporous coatings. Various methods are explored to improve the scratch resistance and mechanical performance, with the introduction of organic chelating agents being particularly promising.
Mesoporous coatings are widely used in industries such as optics, display technologies, photovoltaics, and bioengineering, due to their attractive properties such as high surface area to volume ratio and excellent mass and electron transport characteristics. While structural parameters and material composition can be routinely tailored to the respective applications, improvements in their mechanical properties and robustness, essential for their long-term performance, remain a challenge. Herein, we provide a comprehensive study on the relationship between the degree of porosity, type of material processing and resulting mechanical properties for the use case of mesoporous aluminosilicate thin films that were co-assembled via a sacrificial block copolymer structure-directing agent. Several routes, including the introduction of chelating agents on the precursor solution, a two-step calcination process, and a variation over the aluminium content were explored with the objective of improving the scratch resistance and mechanical properties of the final mesoporous thin film. Pencil hardness tests were combined with atomic force microscopy analysis to investigate the macroscopic scratch resistance, i.e. plastic deformation. Ellipsometric porosimetry served to determine the elastic deformation of the nanoscopic architecture via measurement of the Young's modulus. Our comparative investigation highlights the promising role of organic chelating agents in the sol-gel formulation to slow down the hydrolysis of the aluminium pre-cursor, which facilitated improvements in the mechanical performance close to industrial standard.
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