Litcius/Paper detail

Porous materials: The next frontier in energy technologies

Eliyahu M. Farber, Nicola M. Seraphim, Kesha N. Tamakuwala, Andreas Stein, Maja Rücker, David Eisenberg

2025Science63 citationsDOIOpen Access PDF

Abstract

Porous materials with pore sizes spanning the range from molecular to macroscopic dimensions (from angstroms to centimeters) are essential in electrochemical, thermoelectric, nuclear, and solar power sources and in the extraction of oil, gas, and geothermal heat. To enable the clean, fast, and efficient conversion of energy, the porous structure must be designed to allow, modulate, or block the flow of energy transfer vectors. The most important energy streams are mass, charge, heat, radiation, and pressure, and they must be optimized while packing the optimal surface area per device volume. In this Review, we analyze the physical processes that enable energy transfer in porous structures, highlighting recent advances in the design, characterization, modeling, and fundamental understanding of porosity that have enabled breakthroughs across the landscape of energy technologies.

Topics & Concepts

PorosityPorous mediumEnergy transformationRange (aeronautics)Materials scienceAngstromGeothermal energyEnergy (signal processing)Geothermal gradientBlock (permutation group theory)Solar energyEnvironmental scienceFlow (mathematics)Heat transferEfficient energy useProcess engineeringThermal energyNanotechnologyExtraction (chemistry)Energy storageEnergy transferEngineering physicsEnergy technologyElectricity generationEnergy flowFrontierPower (physics)Energy sourceSolar-Powered Water Purification MethodsNanoporous metals and alloysPhase Change Materials Research