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A new heat storage material could help to significantly improve the energy efficiency of buildings. Developed by researchers at Martin Luther University Halle-Wittenberg (MLU) and the University of Leipzig, it can be used to store surplus heat and release it back into the environment when needed. Unlike existing materials, the new one can absorb significantly more heat, is more stable, and is made of harmless substances. In the Journal of Energy Storage the team describes the formation mechanism of the material.

The invention is a so-called shape-stabilized phase change material. It can absorb large amounts of heat by changing its physical state from solid to liquid. The stored heat is then re-released when the material hardens. “Many people are familiar with this principle from hand warmers,” explains Professor Thomas Hahn from the Institute of Chemistry at MLU. However, the invention from Halle won’t be used in coat pockets. Instead, it could be used by the construction industry as large panels that could be integrated into walls. These would then absorb heat during the sunny hours of the day and release it again later when the temperature goes down. This could save a lot of energy: The researchers have calculated that when the new material heats up, it can store — under the right conditions — up to 24 times per 10 degrees Celsius more heat than conventional concrete or wallboard.

Unlike hand warmers, the panels made of this material mixture do not melt when they absorb heat. “In our invention, the heat storage material is enclosed in a framework of solid silicate and cannot escape due to high capillary forces,” explains Hahn. Most importantly, the substances used in its production are environmentally friendly: harmless fatty acids like those found in soaps and creams. Even the additives that lend the material its strength and increased thermal conductivity can be obtained from rice husks.

In the current study, the team describes the steps involved in creating the structure of the material and how the different chemicals influence each other. For this, the team received support from a group of researchers led by Professor Kirsten Bacia from MLU, who used fluorescence microscopy to visualise the mechanism. “The knowledge we are gaining can be used to further optimise the material and to potentially produce it on an industrial scale,” says Felix Marske, who drove the development forward as part of his doctorate with Thomas Hahn. Until now the material is still only being produced in small quantities in the laboratory. In the future, it can be combined with other steps to help to make buildings significantly more energy efficient or to passively cool photovoltaic systems and batteries, thereby increasing their efficiency.

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Materials provided by Martin-Luther-Universität Halle-Wittenberg. Note: Content may be edited for style and length.



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