Litcius/Paper detail

Significantly Enhanced Mechanical, Thermal, and Ablative Properties of the Lightweight Carbon Fabric/Phenol-Formaldehyde Resin/Siloxane Aerogels Ternary Interpenetrating Network

Jie Zhang, Rongying Yin, Zihao Fan, Xin-Wei Zhou, Haiming Cheng, Changqing Hong, Xinghong Zhang

2024ACS Applied Materials & Interfaces19 citationsDOI

Abstract

Lightweight ablative thermal protection materials (TPMs), which can resist long-term ablation in an oxidizing atmosphere, are urgently required for aerospace vehicles. Herein, carbon fabric/phenol-formaldehyde resin/siloxane aerogels (CF/PFA/SiA) nanocomposite with interpenetrating network multiscale structure was developed via simple and efficient sol–gel followed by atmospheric pressure drying. The ternary networks structurally interpenetrating in macro-, micron-, and the nanoscales, chemically cross-linking at the molecular scale, and silica layer generated by in situ heating synergistically bring about low density (∼0.3 g cm –3 ), enhanced mechanical properties, thermal stability, and oxidation resistance, and a low thermal conductivity of 81 mW m –1 K –1 . More intriguingly, good thermal protection with near-zero surface recession at 1300 °C for 300 s and remarkable thermal insulation with a back-side temperature below 60 °C at 20 mm thickness. The interpenetrating network strategy can be extended to other porous components with excellent high-temperature properties, such as ZrO 2 and SiC, which will facilitate the improvement of lightweight ablative TPMs. Moreover, it may open a new avenue for fabricating multifunctional binary, ternary, and even multiple interpenetrating network materials.

Topics & Concepts

Materials scienceAblative caseSiloxanePhenol formaldehyde resinComposite materialTernary operationPhenolCarbon fibersThermalAerogelFormaldehydeChemical engineeringPolymerComposite numberOrganic chemistryChemistryMeteorologyRadiation therapyMedicineEngineeringInternal medicinePhysicsComputer scienceProgramming languageAerogels and thermal insulationSurface Modification and SuperhydrophobicityPolymer composites and self-healing