The effect of the nano-structured aerogel powder on the structural parameters, water repellency, and water vapor/air permeability of a fibrous polyester material

A water-glass-based silica aerogel was synthesized through an ambient pressure drying method and its structural parameters, hydrophobic property, and blending with a nanofibrous polyester material were investigated. The hybrid aerogel-fibrous materials were prepared using an electrospinning method a...

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Bibliographic Details
Published in:Materials chemistry and physics 2016-07, Vol.177, p.99-111
Main Authors: Mazrouei-Sebdani, Zahra, Khoddami, Akbar, Hadadzadeh, Hassan, Zarrebini, Mohammad, Karimi, Ali, Shams-Ghahfarokhi, Farzaneh
Format: Article
Language:English
Subjects:
Aerogels
Analysis of variance
Droplets
Fibers
Nanostructure
Nanostructures
Permeability
Polymers
Porosity
Sol-gel growth
Surface properties
Water vapor
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Summary:A water-glass-based silica aerogel was synthesized through an ambient pressure drying method and its structural parameters, hydrophobic property, and blending with a nanofibrous polyester material were investigated. The hybrid aerogel-fibrous materials were prepared using an electrospinning method and their hydrophobic and water vapor/air permeation characteristics were analyzed using the SPSS software by one-way ANOVA, Duncan, and 1-sample K-S tests. The BET and BJH analyses showed that the nanosilica aerogel has a pore size of 24 nm and a total pore volume of 3.5 m3/g resulted in 88.6% porosity and 0.2 g/m3 density. The silica aerogel granules showed a high water sliding angle, whereas, the aerogel powder-coated water droplets (marbles) showed a sliding angle of as low as 5°. The SEM and AFM analyses indicated the successful embedding of the aerogel powder into the nanofibrous material with an irregular beads–like structure. The most aerogel content of 4 wt% in the hybrid fibrous material showed a lower mean diameter (176.2 nm) as well as a lower mean size of spaces formed between the super-fine fibers (3598.5 nm) in comparison with the fibrous material with no aerogel content. The beaded fibrous structures of the hybrid fibrous materials led to a suitable two-scale surface roughness with an improved water contact angle up to 130.1° in comparison with 103.4° for the one with no aerogel content. The samples surface energy was remained unchanged with 3 M water repellency of 1. Also, there was no significant difference between the water vapor permeability (WVP) of the samples according to the ANOVA tests with P-values of more than 0.05. The super-fine fibers containing 2 and 4% aerogel have a higher permeability to air in comparison to the pure super-fine fibers and the super-fine fibers containing 0.5 and 1% aerogel, which may be due to the recognized effect on the reduction of the fibers diameter as well as smaller empty spaces formed between the super-fine fibers. •Synthesis and structural/hydrophobic evaluations of the silica aerogel.•Synthesis of the hybrid aerogel/fibrous material through the electrospinning.•Higher hydrophobicity of the aerogel/fibrous material, compared to the pure fibers.•Higher air permeability of the aerogel/fibrous material, compared to the pure one.•Results comparison using the SPSS software (ANOVA, Duncan, and 1-sample K-S tests).
ISSN:0254-0584
1879-3312
DOI:10.1016/j.matchemphys.2016.04.002