Litcius/Paper detail

In-Situ Synthesis of Layered Double Hydroxide/Silica Aerogel Composite and Its Thermal Safety Characteristics

Mengtian Sun, Yang Wang, Xiaowu Wang, Qiong Liu, Ming Li, Yu. M. Shul’ga, Zhi Li

2022Gels35 citationsDOIOpen Access PDF

Abstract

To adjust the thermal safety of hydrophobic silica aerogel, layered double hydroxide (LDH)/silica aerogel (SA) composites were prepared by an in-situ sol-gel process at ambient pressure. This study found the physical combination of SA and MgAl-LDH based on the FTIR spectra and phase composition of LDH/SA. The N2 sorption analysis confirms that the introduction of MgAl-LDH does not change the mesoporous attribution of LDH/SA significantly. With the increase in MgAl-LDH addictive content, the low density (0.12–0.13 g/cm3), low thermal conductivity (24.28–26.38 mW/m/K), and large specific surface area (730.7–903.7 m2g) of LDH/SA are still maintained, which can satisfy the requirements of thermal insulation. The TG-DSC analysis demonstrates that the endothermic effects and metal oxides formed during the MgAl-LDH decomposition are beneficial to the improvement of the thermal stability of LDH/SA composites. In addition, it was found that the gross calorific values of LDH/SA composites decrease with an increase in MgAl-LDH addictive content, all of which are lower than that of the pure SA. The research outcomes indicate that the thermal safety of LDH/SA composites is enhanced significantly by doping MgAl-LDH without impairing too many of the excellent properties, which benefits their expansion in the thermal insulation field.

Topics & Concepts

AerogelMaterials scienceHydroxideThermal stabilityComposite numberComposite materialThermal conductivityThermal decompositionChemical engineeringLayered double hydroxidesSorptionFourier transform infrared spectroscopyEndothermic processChemistryOrganic chemistryAdsorptionEngineeringAerogels and thermal insulationLayered Double Hydroxides Synthesis and ApplicationsSupercapacitor Materials and Fabrication