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A review of thermal hazard formation mechanisms and regulation strategies of hydrophobic silica aerogels

Miao Liu, Zhiyu Huo, Qiao Wang, Yikai Zhu, Shaoqian Zhang, Zhi Li, Qiong Liu, Xiaoxu Wu

2026Journal of Non-Crystalline Solids11 citationsDOIOpen Access PDF

Abstract

Hydrophobic silica aerogels (HSA) are a class of nanoporous materials characterized by low density, high porosity, and ultralow thermal conductivity. Owing to these outstanding properties, HSA have demonstrated great potential as high-performance thermal insulation materials in applications such as building insulation, petrochemical engineering, thermal management for new energy systems, and aerospace. However, with the continuous expansion of their thermal insulation applications, increasing attention has been drawn to the potential thermal hazards introduced by organic moieties grafted during hydrophobic modification. The inherent flammability of HSA severely limits their further application in thermal insulation scenarios with high fire safety requirements. To address this challenge, extensive efforts have been made to investigate the pyrolysis and combustion mechanisms of HSA, which have confirmed that their flammability primarily originates from the introduction of organic groups. Based on this understanding, various strategies, including reducing the content of organic groups, incorporating flame retardants, and applying heat treatment strategy, have been developed to enhance the thermal stability and flame retardancy of HSA. This review systematically summarizes the synthesis methods of HSA, elucidates the origins of their thermal hazards, and critically reviews the current strategies for improving their thermal safety. Furthermore, future research directions are discussed, aiming to provide theoretical guidance and new insights for the safe and efficient application of HSA in thermal insulation fields.

Topics & Concepts

Chemical engineeringMaterials scienceThermalChemistryDegradation (telecommunications)HazardDeposition (geology)Thermal stabilityNanotechnologyNanoparticleAerogels and thermal insulationMesoporous Materials and CatalysisGas Sensing Nanomaterials and Sensors
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