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The efficiency of converting sunlight into electricity or other forms of energy relies heavily on an efficient light-harvesting system that can absorb the entire spectrum of visible light. While plants and bacteria serve as models with their complex light-collecting antennae for photosynthesis, man-made light-harvesting systems have their own limitations. Inorganic semiconductors such as silicon are panchromatic but require thick layers to absorb enough light energy, resulting in bulky solar cells. On the other hand, organic dyes suitable for solar cells are thin but inefficient in absorbing a broad spectral range.

Researchers at Julius-Maximilians-Universität (JMU) Würzburg in Germany have developed an innovative light-harvesting system that addresses the shortcomings of existing systems. This new system absorbs light panchromatically across the visible range like inorganic semiconductors, while utilizing the high absorption coefficients of organic dyes, allowing it to absorb a significant amount of light energy in a thin layer. The team from the Institute of Organic Chemistry at JMU designed the system and collaborated with the Institute of Physical and Theoretical Chemistry to investigate its performance.

The light-harvesting antenna from Würzburg comprises four different merocyanine dyes that are folded and stacked closely together in an intricate arrangement. This arrangement enables rapid and efficient energy transport within the antenna, enhancing its functionality. Known as URPB, the system absorbs various light wavelengths, including ultraviolet, red, purple, and blue, showcasing its versatility in light absorption. Through measuring the fluorescence quantum yield, the researchers confirmed the system’s efficiency in converting 38% of the irradiated light energy into fluorescence, far surpassing the individual dyes’ capabilities of only 1% to 3%.

The successful performance of the novel light-collecting system demonstrates the significance of combining the right dyes and arranging them skillfully to maximize energy absorption. By leveraging the strengths of inorganic and organic materials and mimicking the natural light-harvesting systems seen in plants and bacteria, the researchers have developed a promising solution for enhancing the efficiency of converting sunlight into energy. The URPB system’s ability to absorb a broad spectral range efficiently in a thin layer paves the way for the development of more compact and lightweight solar cells with improved performance. This breakthrough in light-harvesting technology highlights the importance of interdisciplinary collaborations and innovative approaches in developing sustainable energy solutions.

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