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An international research team, including Graz University of Technology, wants to integrate selected microorganisms into façade coatings to bring building walls to life. The microorganisms are intended to protect surfaces, store CO2 and filter pollutants from the air.
External walls of buildings are normally lifeless and have no additional function. An international team of researchers and companies, in which Carole Planchette from the Institute of Fluid Mechanics and Heat Transfer is involved, wants to change this by adding microbial life to building façades. In the project “Archibiome tattoo for resistant, responsive, and resilient cities” (REMEDY), the consortium is working on integrating specifically composed communities of beneficial microorganisms into living ink that adheres to exterior walls made of concrete, wood, metal and other building materials. These living tattoos on buildings are intended to protect the façades from weathering, store CO2 and filter pollutants from the air. The European Innovation Council is funding the four-year project with a total of almost three million euros as part of the Pathfinder funding programme.
Billions of square metres of potential wall space
Over the next 25 years, building façades and roofs with a total area of 9.4 billion square metres will be renovated or newly built in the European Union. "This is a huge potential that we should utilise. Microbiological communities on roofs and façades could fulfil numerous functions without taking up scarce, undeveloped space," says Carole Planchette.
Useful microbiome for buildings
At the University of Ljubljana, a team led by microbiologist Nina Gunde-Cimerman is looking for suitable microorganisms. The researchers want to design interkingdom microbial consortia that form stable communities.
”The aim is to create a beneficial microbiome for buildings that is resistant to pathogenic microbes and repairs superficial cracks on its own,” says Carole Planchette. “Additional benefits will range from carbon sequestration and oxygen production to bioremediation, among others.”
At the Institute of Fluid Mechanics and Heat Transfer, Carole Planchette is responsible for developing a suitable, printable ink in which the microorganisms can survive. “We opted for inkjet printing because it allows us to apply the living ink very precisely, in a controlled manner and quickly at the same time,” explains Carole Planchette. The dimensions of the microorganisms, which reach the size of several micrometres and are expected to aggregate in millimetric clusters, are a challenge: They are too bulky for conventional inkjet technology, in which usually particles in the nanometre range are sprayed. Together with the Slovak inkjet manufacturer Qres Technologies and the Austrian coating specialist Tiger Coatings, Carole Planchette is working on the necessary technological modifications.
Technology breakthrough
“The ambition of REMEDY is to achieve a breakthrough in fundamental research in microbiology and synthetic biology, transfer the know-how to materials science in the form of engineered living materials, and develop compatible biofabrication processes that allow personalised design in the architectural context,” says project coordinator Anna Sandak from the research institute InnoRenew CoE in Izola, Slovenia.
”I am confident that we will develop suitable inks and the customised inkjet technology within the project duration,” says Carole Planchette. "I also expect that we will find suitable microorganisms that survive in the ink and under the stress generated by printing. It will be interesting to see whether we succeed in making this process already fully reproducible over the next four years. Using living - thus evolving - inks for industrial processes such as inkjet printing, which tolerate little parameter variations, is a challenge, as we are entering uncharted territory with the REMEDY project."
The consortium brings together six partners from four EU countries: Slovenia, Austria, the Netherlands, and Slovakia. The collaboration includes InnoRenew CoE acting as coordinator, University of Ljubljana, Graz University of Technology, TIGER Coatings, Xylotrade B.V., and Qres Technologies, with the in-kind support of the University of Primorska as a third party.
Carole PLANCHETTE
Assoc. Prof. Dr. Master
TU Graz | Institute of Fluid Mechanics and Heat Transfer
Phone: +43 316 873 7357
carole.planchette@tugraz.at
A variety of fungal species isolated from building facades in the coastal city of Izola (Slovenia).
Ana Gubenšek
Ana Gubenšek
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A variety of fungal species isolated from building facades in the coastal city of Izola (Slovenia).
Ana Gubenšek
Ana Gubenšek
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