Litcius/Paper detail

Carbon fiber-reinforced carbon foam-based composite phase change materials for efficient photothermal and electrothermal conversion

Zekun Wang, Xiaoguang Zhang, Xin Min, Minghao Fang, Wen Zhang, Peng Cao

2025Journal of Power Sources6 citationsDOIOpen Access PDF

Abstract

Inorganic solid-liquid phase change materials (PCMs) offer significant potential for thermal energy storage but are limited by poor shape stability, leakage, and restricted energy conversion modes. We introduce a novel carbon fiber-reinforced, partially graphitized porous carbon framework (PGC-CF) synthesized via a scalable, cost-effective foaming-assisted catalytic graphitization method – a pioneering approach for PCM composites. This 3D interconnected scaffold encapsulates decanoic acid (CA), forming the PCM (CA@PGC-CF-3) composite with 85.7 % PCM loading and a latent heat capacity of 139.5 J/g. The composite exhibits exceptional shape stability and retains 91.7 % of its latent heat after 300 thermal cycles, driven by the synergistic reinforcement of carbon fibers and a partially graphitized matrix. It achieves photothermal conversion efficiencies of 78.9–95.1 % under 75–200 mW cm −2 solar irradiation and electrothermal efficiencies exceeding 80 % at 3 V, enabled by high thermal (0.3216 W/m⋅K) and electrical (∼26 S/cm) conductivities. Unlike costly graphene- or nanotube-based PCMs, this eco-friendly composite leverages abundant sucrose and carbon fibers, offering a scalable platform for solar energy harvesting, smart building thermal management, and electric vehicle energy storage. • 3D porous carbon scaffold was prepared by foaming-assisted catalytic graphitization. • PGC-CF-3 enables 85 % CA loading, achieving a latent heat capacity of 139.5 J/g. • CA@PGC-CF-3 achieves 95.1 % solar-to-thermal conversion efficiency at 200 mW cm -2 . • The composite exhibits >80 % electrothermal conversion efficiency at just 3 V. • CA@PGC-CF-3 maintains structural integrity and thermal stability after 300 cycles.

Topics & Concepts

Composite numberMaterials scienceCarbon fibersLatent heatEnergy conversion efficiencyThermal energy storageEnergy transformationChemical engineeringThermal stabilityPhotothermal effectThermalPorosityPhase-change materialSolar energyPhotothermal therapyComposite materialThermal conductivityTemperature cyclingReinforced carbon–carbonNanotechnologyThermal energyPhase (matter)Energy storageAerogelCarbon nanofoamCatalysisPhotovoltaic systemPhase Change Materials ResearchSolar Thermal and Photovoltaic SystemsSolar-Powered Water Purification Methods