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Molecular solar thermal energy storage in Dewar pyrimidone beyond 1.6 megajoules per kilogram

Han P. Q. Nguyen, Alexander J. Maertens, Benjamin A. Baker, Nathan M.-W. Wu, Zihao Ye, Qingyang Zhou, Qianfeng Qiu, Navneet Kaur, David B. Berkinsky, Katherine E. Shulenberger, K. N. Houk, Grace G. D. Han

2026Science9 citationsDOI

Abstract

Storing sunlight in a compact and rechargeable form remains a central challenge for solar energy utilization. Molecular solar thermal (MOST) energy storage systems, which harness photon energy and release it as heat on demand, provide a direct approach but have long failed to meet practical benchmarks. Inspired by the architecture of DNA, we report a pyrimidone-based MOST system that stores energy in the strained Dewar photoisomer upon excitation at 300 nanometers. Designed with sustainability in mind, the system operates solvent free and remains compatible with aqueous environments while overcoming one of the field's greatest hurdles-the controlled extraction and transfer of stored heat. When catalyzed by acid, the Dewar isomer releases enough heat to boil water (~0.5 milliliters). These advances help point the way toward decentralized solar heat storage and off-grid energy solutions.

Topics & Concepts

Thermal energy storageSolar energyThermal energyEnergy storageThermalMaterials scienceChemistryProcess engineeringEnergy (signal processing)Heat transferChemical energyExcitationEnergy transferAqueous solutionOptoelectronicsInformation storageFreezing pointHeat energySunlightNuclear engineeringNanotechnologyWork (physics)Solar energy conversionHeat exchangerPhotochemistryComputer data storagePhotovoltaic systemLow energyEnergy technologyOrganic Electronics and PhotovoltaicsCovalent Organic Framework ApplicationsMagnetism in coordination complexes
Molecular solar thermal energy storage in Dewar pyrimidone beyond 1.6 megajoules per kilogram | Litcius