Litcius/Paper detail

Nature-inspired lotus-shaped fins combined with hybrid nanoparticles and metal foam for high-performance latent heat thermal energy storage

Prashant Saini, Julián D. Osorio, Munjal Shah, Umang N. Patel, Akhil Nelapudi, Luis A. Porto-Hernandez

2025International Journal of Heat and Mass Transfer8 citationsDOIOpen Access PDF

Abstract

• Lotus-inspired fins reduce PCM melting time by up to 63%. • Graphene nanoparticles reduce melting time by ∼7%. • Copper foam lowers melting time by over 50% at 75% porosity. • Hybrid fin–nanoparticle–foam design halves charging duration. • Cost-performance analysis guides optimal LHTES design choices. Latent heat thermal energy storage (LHTES) systems play a critical role in renewable energy integration by providing high energy density and nearly isothermal operation during phase transitions. However, their performance is often limited by slow melting/charging rates, which motivates the search for enhanced heat transfer designs. This study investigates the melting behavior of RT-82 phase change material (PCM) using novel lotus-shaped fins combined with copper metal foam and conductive graphene nanoparticles and carbon nanotubes. A two-dimensional enthalpy–porosity model in ANSYS Fluent was developed to simulate the charging/melting process, capturing non-thermal equilibrium between the foam and PCM/nano-PCM. In this study, effects of fin geometry, nanoparticle concentration, and foam porosity on melting dynamics and cost-performance trade-offs were investigated. Results showed that natural convection accelerated melting by ∼12% compared to conduction-only scenarios. Optimized lotus-shaped fins with higher fin density (T3F4 and T3F10) achieved up to 63% faster melting relative to sparse configurations. Graphene nanoparticles improved thermal conductivity, with a 6% volume fraction, by reducing melting time by ∼6.9%, while their combination with 75% porosity foam achieved a maximum reduction in the melting time of ∼51% compared to pure PCM. Cost-performance analysis identified T3F4 as the most balanced design, offering rapid thermal response without excessive material costs, while moderate-density designs like T3S6 provided economical alternatives with acceptable performance. These results highlight the performance enhancement that can be achieved by integrating bio-inspired fins, nanoparticles, and foams, into compact and efficient LHTES for solar heating, building thermal management, and industrial waste-heat recovery applications.

Topics & Concepts

Materials scienceMetal foamPhase-change materialThermal energy storageLatent heatComposite materialHeat transferCarbon nanofoamIsothermal processPorosityNanoparticleNatural convectionPorous mediumCopperFinHeat transfer enhancementGrapheneThermalEnergy storageMelting pointThermal energyCarbon fibersPhase (matter)Enthalpy of fusionThermal conductivityRenewable energyChemical engineeringLiquid metalGraphene foamJoule heatingNanofluidThermodynamicsPhase Change Materials ResearchAdsorption and Cooling SystemsSolar-Powered Water Purification Methods