# High Structural Stability, High Compressive Strength, Excellent Thermal Insulation and Mechanism of Needled Quartz Fiber Felt/Phenolic Aerogel Composites

**Authors:** Dongmei Zhao, Kaizhen Wan, Xiaobo Wan, Yiming Liu, Jian Li, Minxian Shi

PMC · DOI: 10.3390/polym18060705 · Polymers · 2026-03-13

## TL;DR

This paper introduces a lightweight composite material with high strength and excellent thermal insulation, suitable for thermal protection applications.

## Contribution

The study provides a methodological framework for designing aerogel composites by analyzing compressive behavior and heat conduction contributions.

## Key findings

- The composite achieved a thermal conductivity of 0.0646 W·m−1·K−1 and a compressive strength of 7.70 MPa.
- Solid conduction accounted for over 80% of heat transfer in the composite.
- Fiber buckling was identified as the dominant failure mechanism under load.

## Abstract

A lightweight composite that simultaneously exhibits high strength and excellent thermal insulation is of great interest for thermal protection applications. In this study, dimensionally stable needled quartz fiber felt-reinforced phenolic aerogel composites were prepared using vacuum impregnation, sol–gel, and ambient pressure drying. The composites exhibit a multiscale porous structure formed by interconnected nanometer polymer skeletons and micronscale fibers. By regulating the thermoplastic phenolic resin concentration in the precursor solution, the pore structure of the material was refined; the average particle diameter reduced from 99.76 nm to 38.91 nm, and the average pore diameter decreased from 216.79 nm to 49.53 nm. At a phenolic resin concentration of 25%, the composite exhibits outstanding thermal insulation and mechanical properties: a low thermal conductivity of 0.0646 W·m−1·K−1 at room temperature, with a mere 19.5 °C temperature rise on the sample backside after 1800 s heating at 200 °C, and compressive strengths of 7.70 MPa in the XY-direction and 3.87 MPa in the Z-direction (at 10% strain). X-ray micro-CT characterized the internal structural evolution during loading, revealing a failure mechanism dominated by fiber buckling. Theoretical models and experimental data were used to analyze and quantify the contribution rates of gas and solid heat conduction in NQF/PR aerogel composites, with solid conduction accounting for over 80%. Combined with microstructural evolution, the mechanism for the high thermal insulation efficiency of NQF/PR aerogel composites was elucidated. This study prepared NQF/PR aerogel composites with promising application potential. By systematically evaluating their compressive behavior and quantifying the respective contributions of gas and solid conduction, this work provides a methodological framework to guide the rational design of similar aerogel composites.

## Full-text entities

- **Chemicals:** NQF (-), polymer (MESH:D011108), phenolic resin (MESH:C011529), PR (MESH:D011221)

## Full text

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## Figures

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## References

50 references — full list in the complete paper: https://tomesphere.com/paper/PMC13029948/full.md

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Source: https://tomesphere.com/paper/PMC13029948