A rapidly growing interdisciplinary research area combining aerogel and printing technologies that began only five years ago has been comprehensively reviewed.
: The effects of ultrasound (US), thermosonication (TS), ultrasound combined with nisin (USN), TS combined with nisin (TSN), and conventional thermal sterilization (CTS) treatments on the inactivation of microorganisms in grape juice were evaluated. TS, TSN, and CTS treatments provided the desirable bactericidal and enzyme inactivation, and nisin had a synergistic lethal effect on aerobic bacteria in grape juice while not having any obvious effect on the mold and yeast. Compared with CTS, the sensory characteristics of grape juice treated with TS and TSN are closer to that of fresh juice, its microbial safety is ensured, and the physicochemical properties are basically unchanged. More importantly, the total phenolic content and antioxidant capacity of juice treated with TS and TSN were significantly increased, and the total anthocyanin and flavonoid contents were largely retained. Taken together, these findings suggest that TS and TSN has great potential application value and that it can ensure microbial safety and improve the quality of grape juice.
Silica
aerogels are attractive materials for various applications
due to their exceptional performances and open porous structure. Especially
in thermal management, silica aerogels with low thermal conductivity
need to be processed into customized structures and shapes for accurate
installation on protected parts, which plays an important role in
high-efficiency insulation. However, traditional subtractive manufacturing
of silica aerogels with complex geometric architectures and high-precision
shapes has remained challenging since the intrinsic ceramic brittleness
of silica aerogels. Comparatively, additive manufacturing (3D printing)
provides an alternative route to obtain custom-designed silica aerogels.
Herein, we demonstrate a thermal-solidifying 3D printing strategy
to fabricate silica aerogels with complex architectures via directly
writing a temperature-induced solidifiable silica ink in an ambient
environment. The solidification of silica inks is facilely realized,
coupling with the continuous ammonia catalysis by the thermolysis
of urea. Based on our proposed thermal-solidifying 3D printing strategy,
printed objects show excellent shape retention and have a capacity
to subsequently undergo the processes of in situ hydrophobic modification,
solvent replacement, and supercritical drying. 3D-printed silica aerogels
with hydrophobic modification show a super-high water contact angle
of 157°. Benefiting from the low density (0.25 g·cm–3) and mesoporous silica network, optimized 3D-printed
specimens with a high specific surface area of 272 m2·g–1 possess a low thermal conductivity of 32.43 mW·m–1·K–1. These outstanding performances
of 3D-printed silica aerogels are comparable to those of traditional
aerogels. More importantly, the thermal-solidifying 3D printing strategy
brings hope to the custom design and industrial production of silica
aerogel insulation materials.
Native silica aerogels are fragile and brittle, which prevents their wider utility. For designing more durable and stronger silica aerogels, polyvinylmethyldimethoxysilane (PVMDMS) polymers as effective and multifunctional reinforcing agents were used to strengthen methyltrimethoxysilane based silica aerogels (MSAs). The PVMDMS polymer, which was composed of long-chain aliphatic hydrocarbons and organic side-chain methyl and alkoxysilane groups, was integrated into silica networks via a simple sol-gel process. Compared with MSAs, PVMDMS reinforced MSAs (PRMSAs) display many fascinating characteristics. PRMSAs exhibit improved hydrophobic properties (water contact angle of 136.9 ) due to abundant methyl groups in the silica networks. Benefiting from the fine integration of PVMDMS polymers into MSAs, PRMSAs show a perfectly elastic recovery property, the compressive strength of which ranges from 0.19 to 1.98 MPa. More importantly, PVMDMS polymers have successfully suppressed the growth of secondary particles. Homogeneous silica networks formed by nanoscale particles give PRMSAs a high surface area of 1039 m 2 g À1 . Moreover, optimized PRMSAs also exhibit a low thermal conductivity of 0.0228 W m À1 K À1 under ambient conditions, and their thermal stability reaches up to 222.3 C in air. All the results obtained from this paper will help us to design silica aerogels.
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