News Release

New approach paves the way for harvesting and storing solar energy efficiently

Researchers of the universities of Mainz and Siegen have developed novel molecular systems for storing solar energy

Peer-Reviewed Publication

Johannes Gutenberg Universitaet Mainz

storing energy

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Storing energy in chemical bonds using a large fraction of the solar spectrum

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Credit: ill./©: Till Zähringer / JGU

As stated by the International Energy Agency (IEA), approximately 50 percent of global final energy consumption is dedicated to heating. Yet, the utilization of solar power in this sector remains relatively low compared to fossil energy sources. An inherent problem limiting the widespread usage of solar energy is the intermittency of its direct availability. A promising solution comes in the form of molecular solar energy storage systems. Conventional thermal energy storage strategies store the energy for short periods, e.g., in the form of hot water. In contrast, molecular solar energy storage systems store solar energy in the form of chemical bonds, allowing it to be preserved for several weeks or even months. These specialized molecules – or photoswitches – absorb solar energy and release it later as heat, on demand. However, a key challenge for current photoswitches is the trade-off between energy storage capacity and efficient absorption of solar light, limiting the overall performance. To overcome this issue, research teams at Johannes Gutenberg University Mainz (JGU) and the University of Siegen present a novel approach in a collaborative study.

Decoupling the absorption and storing processes of solar energy

The novel class of photoswitches was first introduced by the group of Professor Heiko Ihmels at the University of Siegen, demonstrating exceptional energy storage potential comparable to conventional lithium-ion batteries. However, their functionality was initially limited to activation by UV light, which constitutes only a small portion of the solar spectrum. The research teams at Mainz and Siegen now introduced an indirect light harvesting method, comparable to the function of the light-harvesting complex in photosynthesis. This incorporates a second compound, a so-called sensitizer, which exhibits excellent absorption properties of visible light. "In this approach, the sensitizer absorbs light and subsequently transfers energy to the photoswitch, which cannot be directly excited under these conditions," explained Professor Christoph Kerzig of the JGU Department of Chemistry.

This new strategy has increased solar energy storage efficiency by more than one order of magnitude, representing a major step forward for the energy conversion research community. The potential applications of these systems span from household heating solutions to large-scale energy storage, offering a promising path towards sustainable energy management.

Mechanistic studies essential for reaction discovery and optimization

The Mainz-based team of researchers led by Professor Christoph Kerzig and PhD student Till Zähringer conducted detailed spectroscopic analyses to explore the complex system, which were essential for understanding the underlying mechanism. Each reaction step was carefully examined by the paper's first author, Till Zähringer, resulting in a thorough understanding of how the system operates. "By doing so, we could not only push the light-harvesting limit substantially but also improve the conversion efficiency of light to stored chemical energy," explained Zähringer. Under operational conditions, each absorbed photon can trigger a chemical bond formation process, which is rarely observed in photochemical reactions owing to several energy loss channels. The scientists successfully validated the system's robustness and practicality by cycling between the energy storage state and the energy release state multiple times employing solar light, highlighting its potential for real-world applications.

The results have been published in Angewandte Chemie, where the work has been classified as a Hot Paper due to exceptional evaluations from scientific reviewers.

This research project received financial support from the German Research Foundation (DFG) and the German Federal Environment Foundation, providing a project grant to Christoph Kerzig and a fellowship to Till Zähringer, respectively. Further support came from the House of Young Talents and the Stiftung Nagelschneider of the University of Siegen.


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