Maximizing natural light in buildings is popular and can save on energy costs. However, traditional glass roofs and walls also present problems such as glare, lack of privacy, and overheating. Alternative solutions, such as coatings and light-diffusing materials, have not yet provided a comprehensive remedy.
Credit: Gan Huang, KIT
Maximizing natural light in buildings is popular and can save on energy costs. However, traditional glass roofs and walls also present problems such as glare, lack of privacy, and overheating. Alternative solutions, such as coatings and light-diffusing materials, have not yet provided a comprehensive remedy.
New Material Combines Multiple Functions
Researchers at the Institute for Microstructure Technology (IMT) and the Light Technology Institute (LTI) at KIT have now developed a novel polymer-based metamaterial that combines various properties and could replace glass components in construction in the future. This Polymer-based Micro-Photonic Multi-Functional Metamaterial (PMMM) consists of microscopic pyramids made of silicone. These micro-pyramids measure about ten micrometers, which is about one-tenth the diameter of a hair. This design gives the PMMM film several functions: light diffusion, self-cleaning, and radiative cooling while maintaining a high level of transparency. “A key feature is the ability to efficiently radiate heat through the Earth’s atmosphere’s long-wave infrared transmission window, releasing heat into the cold expanse of the universe. This allows for passive radiative cooling without electricity consumption,” explains Bryce S. Richards, Professor at IMT and LTI.
Cooling, Light-Transmissive, and Glare-Free
In the lab and in experiments under open skies under real outdoor conditions, the researchers tested the material’s properties and measured its light transmittance, light scattering, reflection properties, self-cleaning ability, and cooling performance using modern spectrophotometry. The results: The tests achieved cooling of 6 °C compared to the ambient temperature. Additionally, the material showed a high spectral transmittance, or transparency, of 95 percent. In comparison, glass typically has a transparency of 91 percent. At the same time, the micro-pyramid structure scatters 73 percent of the incoming sunlight, resulting in a blurry appearance. “When the material is used in roofs and walls, it allows for bright yet glare-free and privacy-protected indoor spaces for work and living. In greenhouses, the high light transmittance could increase yields because the photosynthesis efficiency is estimated to be nine percent higher than in greenhouses with glass roofs,” says RichardsGan Huang, a Group Leader at IMT. The micro-pyramids also give the PMMM film superhydrophobic properties, similar to a lotus leaf: water beads up in droplets and removes dirt and dust from the surface. This self-cleaning function makes the material easy to maintain and durable.
Potential for Construction and Urban Development
“Our newly developed material has the potential to be used in various areas and makes a significant contribution to sustainable and energy-efficient architecture,” explains Richards. “The material can simultaneously optimize the use of sunlight indoors, provide passive cooling, and reduce reliance on air conditioning. The solution is scalable and can be seamlessly integrated into plans for environmentally friendly building construction and urban development,.” says Huang.
Last year, the Karlsruhe research team already won first place at the Public Choice Award of the Helmholtz Best Scientific Image competition.
Original Publication
Gan Huang, Ashok R. Yengannagari, Kishin Matsumori, Prit Patel, Anurag Datla, Karina Trindade, Enkhlen Amarsanaa, Tonghan Zhao, Uwe Köhler, Dmitry Busko, Bryce S. Richards: Radiative cooling and indoor light management enabled by a transparent and self-cleaning polymer-based metamaterial, Nature Communications volume 15, Article number: 3798 (2024). DOI: 10.1038/s41467-024-48150-2
Being “The Research University in the Helmholtz Association”, KIT creates and imparts knowledge for the society and the environment. It is the objective to make significant contributions to the global challenges in the fields of energy, mobility, and information. For this, about 10,000 employees cooperate in a broad range of disciplines in natural sciences, engineering sciences, economics, and the humanities and social sciences. KIT prepares its 22,800 students for responsible tasks in society, industry, and science by offering research-based study programs. Innovation efforts at KIT build a bridge between important scientific findings and their application for the benefit of society, economic prosperity, and the preservation of our natural basis of life. KIT is one of the German universities of excellence.
kar, 10.05.2024
Journal
Nature Communications
Method of Research
Case study
Subject of Research
Not applicable
