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Gradient nanofiber aerogels for extreme cryogenic and thermal environments

Chunmei Li, Rui Xu, Dong Han, Puhao Li, Wei Liu, Mingjian Guang, Xujiang Chao, Peng Wang

2026Nature Communications6 citationsDOIOpen Access PDF

Abstract

Striking a balance between sensitivity and detection range while ensuring stability under extreme temperatures remains a formidable challenge in the design of flexible pressure sensors. To address this issue, we draw inspiration from the multi-gradient architectures of nature and propose a bottom-up self-assembly strategy. By leveraging a meticulously orchestrated multi-step approach that encompasses electrospinning, sequential freezing, and thermal imidization, we successfully fabricate a polyimide nanofiber/carbon nanotube dual-gradient aerogel with a dynamic stiffness transition from flexible to rigid states. Experimental results highlight notable properties of the dual-gradient aerogel, which exhibits an ultralow density (0.023 g cm−3), efficient thermal insulation (28 mW m−1 K−1), and reliable compressibility and fatigue resistance. Moreover, it establishes a favorable equilibrium between sensitivity (156 MPa−1) and an extensive detection range (223 kPa). Notably, the combination of thermal resilience (−196 °C to 533.30 °C) and mechanical stability enables performance that is comparable to, or in some aspects surpasses, that of conventional flexible sensing materials. This dual-gradient aerogel provides both effective thermal insulation and high-precision physiological monitoring under extreme conditions, offering integrated thermal protection and real-time astronaut health assessment in spacesuits. Inspired by nature, this study reports a dual-gradient aerogel via freeze-casting. It blends flexibility with rigidity, offers high sensitivity and wide range, withstands extreme heat and cold, with promise for integration in spacesuits.

Topics & Concepts

AerogelMaterials scienceThermal insulationThermalThermal stabilityStiffnessResilience (materials science)Sensitivity (control systems)NanofiberRange (aeronautics)NanotechnologyMicroscale chemistryPolyimideComposite materialThermal management of electronic devices and systemsPolymerCarbon nanotubeAmbient pressureHoneycombThermal protectionNanosensorCompressibilityAtmospheric temperature rangeThermal bridgeFlexibility (engineering)NanomaterialsTemperature gradientThermal conductivityAdvanced Sensor and Energy Harvesting MaterialsAerogels and thermal insulationSpaceflight effects on biology
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