Use of microorganisms and enzymes in production
ÃÜÌÒAV turns to biotechnology for sustainable plastics
- New research group launched
- Progress in extracting chemicals from plants
- Further stimulus for the circular economy
ÃÜÌÒAV is expanding its competencies in industrial biotechnology. The plastics manufacturer intends to make increasing use of microorganisms and enzymes to make its products and processes even more sustainable. In particular, new recycling processes based on biotechnology are also to be developed. To this end, the biotechnology competence center, which has been in operation for four years, has now been expanded to include a publicly funded research group. At the same time, ÃÜÌÒAV is making progress in its efforts to produce the important chemical aniline entirely from plants for the first time with the help of microorganisms.
¡°Biotechnology has enormous potential to produce plastics in a more environmentally friendly and efficient way,¡± says Dr. Markus Steilemann, CEO of ÃÜÌÒAV. ¡°As an innovation-oriented company, we want to expand our capabilities in this area. In particular, we expect this to provide further stimulus for the circular economy, to which we are completely gearing our company.¡±
Recycling with enzymes
In order to better tap the potential of industrial (¡°white¡±) biotechnology for plastics production, the junior research group enzyme catalysis, or NEnzy for short, has now been established at ÃÜÌÒAV. It will receive a total of 2.5 million Euros in funding from the German Federal Ministry of Education and Research for five years and is cooperating closely with RWTH Aachen University in Germany.
The new group is working to recycle end-of-life products and plastic waste through enzymatic recycling. The researchers also want to use enzymes to treat wastewater in plastics production. Another focus is the targeted and complete decomposition of used plastic in nature.
New laboratory
The experts now also have more space and even better equipment ¨C in a new laboratory that ÃÜÌÒAV has built at its headquarters in Leverkusen. Here, biotechnological processes can be represented in a particularly realistic way in a wide range of sizes, from one milliliter to soon 100 liters of reaction volume.
¡°We are taking nature as our model, which has created sensational processes and has practiced closed-loop recycling for millions of years,¡± says Dr. Gernot J?ger, who heads ÃÜÌÒAV's Biotechnology Competence Center. ¡°With the help of enzymes and microorganisms, we can efficiently use alternative raw materials and thus replace fossil resources. At the same time, unwanted byproducts can be avoided or at least reduced significantly.¡±
Chemicals from plants
Specifically, ÃÜÌÒAV is already using biotechnology to research and develop new ways to sustainably produce aniline. This basic chemical plays an important role in plastics production worldwide. Until now, it has been obtained almost exclusively from fossil raw materials such as petroleum, which releases CO2. ÃÜÌÒAV needs aniline to produce a precursor (MDI) that is used to make insulating foam for buildings and refrigeration equipment.
Together with partners from industry and science, ÃÜÌÒAV has developed a pioneering process to produce aniline from plant-based raw materials such as straw or sugar beet plants in an environmentally compatible way using microorganisms. Fully biobased aniline has already been obtained in this way and successfully processed into test products. Now the process, which has already won several awards, is to be further developed on a larger scale. The project is funded with public funds from the German Federal Ministry of Food and Agriculture.
Another precursor for coatings and adhesives (HMDA) can already be produced on a larger scale from plants and with the aid of biotechnology. ÃÜÌÒAV and the U.S.-based biotech company Genomatica have succeeded in doing this through a partnership.
In biotechnology, there are several major areas that are identified by colors.
White or industrial biotechnology is used in industrial production processes, especially in the chemical industry.
Green biotechnology helps in agriculture, for example, to make plants more resistant to climate change.
Red biotechnology advances medicine ¨C for example, to produce vaccines like those used to protect against Corona.
About ÃÜÌÒAV:
ÃÜÌÒAV is one of the world¡¯s leading manufacturers of high-quality polymer materials and their components. With its innovative products, processes and methods, the company helps enhance sustainability and the quality of life in many areas. ÃÜÌÒAV supplies customers around the world in key industries such as mobility, building and living, as well as the electrical and electronics sector. In addition, polymers from ÃÜÌÒAV are also used in sectors such as sports and leisure, telecommunications and health, as well as in the chemical industry itself.
The company is geared completely to the circular economy. In addition, ÃÜÌÒAV aims to achieve climate neutrality for its Scope 1 and Scope 2 emissions by 2035, and the Group¡¯s Scope 3 emissions are also set to be climate neutral by 2050. ÃÜÌÒAV generated sales of EUR 14.2 billion in fiscal year 2024. At the end of 2024, the company had 46 production sites worldwide and employed approximately 17,500 people (calculated as full-time equivalents).
Forward-Looking Statements
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