Alternative construction materials: mycelium-based materials - 20/12/2023

Using fungi to create sustainable and economical mycelium-based materials

Most of us see fungi as just food - and possibly pathogens. This is a mistake, because these amazing organisms are capable of much more: they grow on plant residues of all kinds, forming a dense and interconnected structure as they spread. The resulting material can be moulded into desired shapes and be turned into new sustainable and economically attractive products such as leather and polystyrene substitutes or building materials.

Sustainable binder alternative - 18/12/2023

Copied from insects: new biological wood binder under development

Plastic is all around us; and unfortunately, it is not going away any time soon. The search for more sustainable solutions is fully underway. However, binders that degrade only with difficulty or not at all are still used to bond natural materials such as wood and straw - not yet truly environmentally friendly. Fraunhofer researchers are working on an insect-inspired wood binder that makes bonded wood products both resistant and biodegradable.

Wasser 3.0: #detect|remove|reuse - 31/10/2023

How to sustainably remove and recycle microplastics from water

We all pollute our water with things we use in our everyday lives. In the process, microplastics and micropollutants accumulate in sometimes significant quantities and are difficult to remove. This has increasingly devastating consequences for our health and the environment. Wasser 3.0, a non-profit start-up from Karlsruhe, has declared war on this problem by developing a customisable process to detect, remove and even recycle these pollutants.

Textiles are a given in civil engineering. Until now, textiles made of resistant synthetic fibers have been used for this purpose, having a long lifetime. For some applications, however, it would not only be sufficient but even desirable for the auxiliary textile to degrade when it has done its job. Natural fibers, in contrast, often decompose too quickly. The DITF are developing a bio-based protective coating that extends their service life.

Microorganisms degrade biobased turf infill - 17/10/2023

Eco-friendly artificial turf: a sports pitch that’s good for people and the environment

There are thousands of artificial turf pitches in Germany. They are extremely practical, but often not at all environmentally friendly. When it rains or the pitch is used, plastic particles from the rubber granules can be released into the envronment, where they remain. Researchers at the University of Stuttgart along with the company TECNARO are now developing an artificial turf with an infill that biodegrades as soon as it leaves the pitch.

Industrial biocatalysis with enzymes is deemed to be a “game changer” in the development of a sustainable chemical industry. Enzymes can be used to synthesize an impressive range of complex molecules. Researchers of KIT have now developed a new class of materials by producing enzyme foams of tremendous stability and activity. The researchers have already filed a patent application on the process to produce enzyme foams.

Innovative materials - 14/06/2023

Reinventing ‘wood’ with programmable bacteria

Conserving wood by producing furniture and other objects from wood-based materials with the help of microorganisms? That is exactly what a team of researchers from the University of Freiburg and the Leibniz Institute for New Materials (INM) in Saarbrücken is working on in the DELIVER project. The aim is to create a database of materials with a broad range of controllable properties for various applications that can be produced from wood waste.

3D-Thermocell project - 17/05/2023

Paper instead of plastic: sustainable packaging with a good conscience

Replacing plastic – for example in packaging – is not that easy but nevertheless urgently needed. In the 3D-Thermocell project, researchers at DHBW Karlsruhe are currently developing new plastic substitute products made of thermoformable paper as a renewable resource, which should be cheap and light and easy to dispose of along with waste paper. The characterisation and application of demonstration models will start soon.

Sustainability is a major challenge in the food and packaging industry. Plastic packaging is being replaced by organic-based and biodegradable materials, but it must still fulfill high functional requirements. A team of researchers at the University of Hohenheim has developed a new coating system that is both water-impermeable, heat-resistant, and mechanically durable as well as being suitable for consumption, and biodegradable at the same time.

Milana will strengthen the research of the Cluster of Excellence Living, Adaptive and Energy-autonomous Materials (livMatS) in the field and work closely with scientists from the Freiburg Center for Interactive Materials and Bioinspired Technologies (FIT) and the Freiburg Materials Research Center (FMF).

Composite materials provide stability in aircraft parts, sports equipment, and everyday household items. However, most of these materials have a poor carbon footprint and are not naturally degradable. A more sustainable alternative has been developed by a team from the University of Stuttgart. This completely bio-based composite material is made of flax fibers and the biopolymer chitosan.

Start for an EU-wide collaborative project: Under the leadership of the French company Fairbrics SAS, 17 project partners from 7 European countries are coming together. The common goal is to produce end products from polyester in a closed cycle using industrial CO2 emissions and to bring them to market maturity. The DITF produce synthetic fibers from plastics of non-fossil origin.

A polyester plastic of great mechanical stability, which is also easily recyclable and even compostable: Stefan Mecking, chemist at the University of Konstanz, and his research group present a new material.

The German Research Foundation (DFG) has awarded the 2023 Gottfried Wilhelm Leibniz Prize to Prof. Achim Menges, head of the Institute for Computational Design and Construction at the University of Stuttgart. The award, which is endowed with EUR 2.5 million, is considered by many the most important research prize in Germany.

The Carl Zeiss Foundation is funding the "DELIVER - Data-driven Engineering of Sustainable Living Materials" project at the University of Freiburg in its "CZS Wildcard" program. In the project, scientists from the Freiburg Clusters of Excellence CIBSS and livMatS will develop sustainable wood-based materials whose properties can be precisely controlled.

Across the EU, more than 300 billion items of packaging are not recycled every year because they consist of a mixture of different materials. Monomaterial packaging on the other hand is easy to recycle. However, it needs to be coated with ultra-thin barrier layers to protect delicate products just as well as compound materials do.

The University of Stuttgart is contributing to innovations for climate protection as part of the EU project "Smart Circular Bridge". An old material is being rediscovered: flax has been with us for thousands of years in the form of clothing, sacks, and robust ship's ropes. Now the plant fibres are experiencing a renaissance and could become the building material of the future.

Natural fibers in use - 15/02/2022

Sustainable reinforcement of e-bike battery cases

Ansmann AG from Assamstadt provides mobile energy solutions with a focus on sustainability. The BioBattery project, which was awarded the Baden-Württemberg Bioeconomy Innovation Prize, saw Ansmann AG working with the Fraunhofer LBF in Darmstadt to develop a natural fibre reinforced plastic composite for use in e-bike battery cases.

Article - 19/09/2019

Magnetised algae as microrobots for medical and environmental purposes

Algae, for most of us, is something that lives in water courses that we occasionally find unpleasant. However, that is to do them a wrong. These extremely versatile and frugal organisms might in future prove to be extremely important. Scientists at the University of Stuttgart are investigating how algae can be used as microrobots in biomedicine and environmental remediation.