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27.11.2024 14:15

Development of climate-neutral building materials through biogenic production using phototrophic microorganisms

Annett Arnold Kommunikation
Fraunhofer-Institut für Elektronenstrahl- und Plasmatechnik FEP

    The Fraunhofer Institute FEP in Dresden offers scalable research and development opportunities focused on technological innovations for resource conservation and climate neutrality. To meet the rising demand for climate-neutral building materials, new manufacturing processes are being explored. The institute researches electron beam-assisted processes to enhance biogenic limestone synthesis with phototrophic microorganisms, supporting the decarbonization of the cement industry. This aims to reduce the CO2 footprint of cement and gradually replace fossil limestone.
    The project will be presented at the BAU 2025 trade fair in Munich from January 13 to 17, 2025, at the Fraunhofer joint booth.

    Due to the close links between Fraunhofer FEP and industry, the results of applied research are transferred into a wide range of applications and products. A particular focus is directed on the strategic research fields of sustainability, life science and environmental technologies, and in application fields such as the construction sector and smart buildings. In particular, low-energy, non-thermal electron beam technology is a multifunctional tool with omnipotent potential for use in a wide range of environmental and biotechnological applications and can be integrated into existing production lines. Due to growing demands for sustainable and resource-saving processes and to achieve climate targets, the need for bio-based substitution processes in the construction sector is also growing. For ecologically relevant issues, such as the biotechnological extraction of resources, the scientists at Fraunhofer FEP can utilize the chemical and biological effects of low-energy accelerated electrons for application-specific process development.

    Germany has set itself the ambitious goal of achieving climate neutrality by 2045 and reducing greenhouse gas emissions under the Climate Protection Act, which represents an enormous challenge for the industry. The construction sector is one of the world's largest economic sectors, which is why climate-neutral and circular construction of the future will require a wide range of transformations. The development of new bio-based and sustainable materials to permanently capture CO2 is a starting point for research and development that project manager Dr. Ulla König is working on in her Biocompatible Materials group at the Fraunhofer FEP.

    Cement, the world's most widely produced material, is indispensable as a binding agent in the construction industry, with global cement consumption continuing to rise due to population growth, urbanization and increasing infrastructure development. The cement industry is a major source of greenhouse gas emissions, which is why climate neutrality in this sector can only be achieved through alternative approaches. Decarbonization is therefore a promising strategy in which the development of CO2-reduced cements will be an essential task.

    At Fraunhofer FEP, researchers in the Biocompatible Materials Group, in cooperation with the institute's own biomedical service laboratory, are conducting intensive research into the biogenic material development of secondary limestone using phototrophic microorganisms that consume CO2. These are able to fix and convert carbon dioxide from the atmosphere through photosynthesis. The focus of the research is to be able to implement the process of microbiological limestone formation, which has existed in nature for billions of years, on an industrial scale and to improve its productivity so that low-emission building materials can be produced in later stages that permanently capture CO₂ and thus make a sustainable contribution to the circular economy.

    Group manager Dr. Ulla König explains: “The optimization and scalability of biogenic limestone synthesis based on the microbial biomineralization process plays a key role for future large-scale applications. At Fraunhofer FEP, we have therefore combined the optimization of the biomineralization of phototrophic microorganisms with a novel approach. To this end, we utilize the biostimulating potential of electron beam technology. We are tapping into the dose-dependent biopositive effect of low-energy, non-thermal electron beam processes on the metabolic processes of phototrophic microorganisms in order to increase the effectiveness and efficiency of biogenic limestone synthesis.”

    As part of collaborations, circular manufacturing processes can then be developed in the next stage of development, including the recycling of waste and residual materials to create sustainable, bio-based building and construction materials. At the BAU 2025 trade fair in Munich from January 13 - 17, 2025, the scientists will present these new research approaches and other perspectives at the joint Fraunhofer stand and will be available for discussions on joint project ideas and research projects.

    ****************************************
    Press contact:

    Ms. Annett Arnold

    Fraunhofer Institute for Electron Beam and Plasma Technology FEP
    Phone +49 351 2586 333 | presse@fep.fraunhofer.de
    Winterbergstraße 28 | 01277 Dresden | Germany | www.fep.fraunhofer.de


    Weitere Informationen:

    https://s.fhg.de/wXZJ


    Bilder

    Fraunhofer FEP photobioreactor for the cultivation of phototrophic microorganisms on a laboratory scale under defined light, temperature and gas conditions
    Fraunhofer FEP photobioreactor for the cultivation of phototrophic microorganisms on a laboratory sc ...
    Finn Hoyer
    © Fraunhofer FEP

    REAMODE – Test facility for the modification of organic materials with accelerated electrons
    REAMODE – Test facility for the modification of organic materials with accelerated electrons
    Finn Hoyer
    © Fraunhofer FEP


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