Physicochemical Characterization of Interfacial Defect Reduction in Superficially Modified Hydrophobic SiO2-Aerogel Composites

Physicochemical Characterization of Interfacial Defect Reduction in Superficially Modified Hydrophobic SiO2-Aerogel Composites

The aim of this research is to reduce the number of defects caused by the hydrophobicity of silica aerogel (SA) in the interfacial transition zone formed by this solid aggregate and a liquid binder in an alternative construction composite (paste). A new technique for controlling compatibility issues...

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Bibliographic Details
Published in:SILICON Vol. 16; no. 9; pp. 3929 - 3940
Main Authors: Valdez-Cano, R., Gonzalez-Lopez, J. R., De-Los-Santos, E. U., Amaya-Gallardo, E., Inzunza-Aragón, I., Mendoza-Rangel, J. M., Díaz-Aguilera, J. H.
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-06-2024
Springer Nature B.V
Subjects:
Adhesive strength
Adhesives
Chemistry
Chemistry and Materials Science
Contact angle
Copolymers
Defects
Environmental Chemistry
Free surfaces
Hydrophobicity
Inorganic Chemistry
Lasers
Materials Science
Optical Devices
Optics
Particulate composites
Photonics
Physical properties
Polymer Sciences
Pore size
Porosity
Silica aerogels
Silicon dioxide
Surface energy
Surfactants
Thermal conductivity
Thermodynamic properties
Wettability
Silica aerogel
Surface modification
Alternative composite
Porosity
Surface free energy
Wettability contact Angle
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Summary:The aim of this research is to reduce the number of defects caused by the hydrophobicity of silica aerogel (SA) in the interfacial transition zone formed by this solid aggregate and a liquid binder in an alternative construction composite (paste). A new technique for controlling compatibility issues has been developed by modifying the chemicals and physical properties involved, evaluating two surfactants that function as elements that increase adhesion strength. The characteristics of wettability and free surface energy are beneficial for macroscopic morphology, microscopic structure, porosity, pore size, and physisorption, and they influence the mechanical and thermal properties of the composites. The contact angle shows that the composites obtained with the smallest SA particle size modify the wettability of the composite, increasing the contact angle to 136°, thus approaching the limit of superhydrophobic surfaces. Conversely, the composites with the large SA particles sizes decrease the angle to 94°, approaching the hydrophilic limit. The copolymer (COP) is the most efficient surfactant, achieving high surface energies, sometimes doubling those of composites integrated with only SA. Microscopy images show the presence of additional compact and homogeneous composites, with few separations and cracks. Additionally, the porosity increases to a total pore volume of 0.3376 cm 3 /g, and the specimen has an average pore size of 26.576 nm and a surface area of 50.811 m 2 /g. The compounds modified with the copolymer A3100COP and A3110COP and those modified with A3100S and silane (S) achieve great efficiency, with a mechanical strength of 5.19 MPa and a thermal conductivity of 0.141 W/(m·K) after 28 days.
ISSN:1876-990X
1876-9918
DOI:10.1007/s12633-024-02978-x