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Programmable Shape‐Morphing Enables Ceramic Meta‐Aerogel Highly Stretchable for Thermal Protection

Xuan Zhang, Jianyong Yu, Yang Si

2024Advanced Materials19 citationsDOI

Abstract

Abstract Ceramic aerogels hold significant potential for thermal insulation, yet their mechanical stretchability and thermal stability fall short in extreme environments. Here, the study presents a programmable shape‐morphing strategy aimed at engineering a binary network topology structure within ceramic aerogels to effectively dissipate stress and block heat transfer. The special topology design, which includes kirigami lamellated aerogels for bearing loading stress and randomly assembled aerogels for mechanical energy pre‐storage to transfer tensile stress, effectively achieves unexpected mechanical tensile properties and thermal stability. The resulting robust meta‐aerogels demonstrate remarkable structural stability with topology‐derived mechanical tensile of up to 85% strain, excellent resilience to 500 cycles of 50% tensile strain, 1000 cycles of 60% buckling strain, and 500 cycles of 50% compressive strain, temperature‐invariant tensile recovery capability; simultaneously, low thermal conductivity of 33.01 mW m −1 K −1 and tensile‐invariant thermal insulation makes the ceramic meta‐aerogels an ideal substitute material for various applications.

Topics & Concepts

Materials scienceAerogelComposite materialUltimate tensile strengthThermal insulationCeramicThermal conductivityMorphingComputer scienceComputer visionLayer (electronics)Aerogels and thermal insulationAdvanced Materials and MechanicsAdvanced Sensor and Energy Harvesting Materials
Programmable Shape‐Morphing Enables Ceramic Meta‐Aerogel Highly Stretchable for Thermal Protection | Litcius