back to top
My wish lists
Save your wish list
If you want to add more content to your wish list, simply log in. If you do not have a user account, please register for the Hanser Customer Center.

» Do you already have a user account? Please log in here.
» Don't have a user account yet? Please register here.
Your wish lists
If you want to use your wish list during your next visit, simply log in. If you do not have a user account, please register for the Hanser Customer Center.
» Do you already have a user account? Please log in here.
» Don't have a user account yet? Please register here.

« Back

Your advantages at a glance

  • One login for all Hanser portals
  • Individual home page for faster access to preferred content
  • Exclusive access to selected content
  • Personal wish lists on all portals
  • Central management of your personal information and newsletter subscriptions

Register now
Bookmark Bookmarked

Extremely Resilient, Extremely Lightweight

Scientists from Saxony-Anhalt Create Super Polymer Fibers

Experts and researchers from Halle-Wittenberg in Saxony-Anhalt, Bayreuth, Nanchang and Zurich have managed to produce unique polymer fibers that are distinctive for being extremely resilient while also very lightweight.

Drawn a multifibrillar polyacrylonitrile fiber (© Universität Bayreuth/J.Rennecke)

With the help of researchers from the Martin Luther University Halle-Wittenberg in Saxony-Anhalt, experts from Bayreuth, Nanchang and Zurich have managed to produce unique polymer fibers. These fibers are distinctive for being extremely resilient while also very lightweight. They have many potential uses, including in the automotive industry.
It would not have been possible to understand the unique properties of the super polymer fibers without the scientists at the Martin Luther University Halle-Wittenberg (MLU).

The Research Group for Microstructure-Based Material Design at the Institute of Physics, led by Prof. Ralf Wehrspohn, used a device known as the ZEISS Xradia 810 Ultra. This is a high-resolution three-dimensional X-ray computed tomography which was able to characterize the fibers. The technology allows scientists to create highly detailed 3D images of small samples. When the researchers modeled the fibers, they saw for the first time that the fibrils within each individual fiber are almost always arranged in the same lengthwise direction.

Dr. Juliana Martins de Souza e Silva, Group Lead for the X-ray electron microscope at the MLU and a habilitation candidate in Prof. Wehrspohn’s research group, explains what the 3D images show together with the other findings: “Only the combination of a highly fibrillated orientation caused by stretching and tempering in the presence of a certain amount of poly bisazide as an interconnected molecule resulted in high strength and toughness as well as a high degree of crystallinity in a lightweight material.”

Extremely Resilient

The fibers, which are chemically based on polyacrylonitrile, are remarkable for their extreme resilience and tensile strength while at the same time being extremely lightweight. One individual fiber with a diameter of around 0.04 mm comprises up to 4,000 ultra-thin fibrils. The additive – i.e., the connecting molecule – joins the fibrils in the fiber together with favorable results.

However, it is not just the additive that is responsible for making the material strong, but also the fact that it is combined with the orientation of the many fibrils, which is a result of the stretching and heat treatment used during the manufacturing process. By way of comparison, an individual fiber is no thicker than a human hair and weighs less than a fruit fly but can nevertheless lift 30 g in weight.

There are few synthetic materials that combine such high strength with extreme toughness. The scientists from Halle mastered these important technological challenges together with researchers from the University of Bayreuth, Jülich Research Center and other partners in Germany, China and Switzerland.

The polymer fibers they produced withstand deformation and fractures because they can stretch and then return to their original shape, meaning they can absorb lots of energy. “As well as being lightweight, the fibers are unique because it was difficult until now to combine high strength with high toughness in one material,” says Martins de Souza e Silva.

Many Potential Uses

Due to their unique properties, the fibers are ideally suited to use in technical components subject to high loads. For example, they could be used as a material for parachutes and protective gear in the textile industry or for artificial tendons and ligaments, tissue repair materials or surgical sutures in medical engineering.

It is equally possible that they could be put to use in the aerospace industry as well as the automotive industry, where they could, explains Martins de Souza e Silva, be used in the manufacture of abrasion-resistant tires and other vehicle parts, helping to reduce the vehicle’s weight. Yet another benefit of the fibers is that they are recyclable.

The scientists believe that the material could undergo further development: “Our fibers use an innovative design principle that would also allow similarly strong, tough fibers to be produced from other standard polymers. Different combinations of polymers and linker molecules could therefore lead to the creation of new materials.”

For now though, the polymer fibers discovered by the teams in Halle, Bayreuth, Nanchang and Zurich can be made straightforwardly using high-tech processes established in the sector. “We expect that our fibers will soon be put to practical use in industry,” says Martins de Souza e Silva.

Anja Falgowski, IMG Saxony-Anhalt

Additional information
  • 11-02-2020

    Efficient Methods of Recycling Composite Materials

    AIMPLAS Coordinates European Sparta Project

    The main goal of the European Sparta project is to find a new method of recycling and reprocessing composite thermoplastic materials that reduces the amount of waste generated by the aerospace industry, as well as its environmental impact.   more

  • 10-22-2020

    Polystyrene Is Mechanically Recyclable to Food Contact Standards

    Styrenics Circular Solutions (SCS) in Cooperation with Fraunhofer-Institut IVV

    Styrenics Circular Solutions (SCS), the value chain initiative to increase the circularity of styrenic polymers, has successfully demonstrated that polystyrene is mechanically recyclable to food contact standards.   more

  • 10-13-2020

    Honeycomb Cores for Sustainable Concept Car

    Car Made Entirely out of Recycled Materials

    Together with industrial partners, students at Eindhoven University of Technology have developed a concept car made entirely from recycled materials. Important lightweight components are recycled PET honeycomb cores.   more

Company profile

IMG Investitions- und Marketing- gesellschaft Sachsen-Anhalt mbH

Am Alten Theater 6
DE 39104 Magdeburg
Tel.: 0391 56899-0
Fax: 0391 56899-50

These articles might be interesting for you

Would you like to subscribe to our Newsletters on plastics technology and profit from the latest information?

Subscribe here

Subscribe here