Press

High-performance, long-lasting energy storage devices are crucially important for many future-oriented technologies: e.g. for electromobility, for mobile end devices such as tablets and smartphones as well as for the efficient use of energy from renewable sources. Dr. Daniel Mutter from the Freiburg-based Fraunhofer Institute for Mechanics of Materials (IWM) was able to clarify what the chemical composition of solid ceramic electrolytes should be in order to ensure good performance in lithium-ion batteries. The research was published in the Journal of Applied Physics (https://doi.org/10.1063/1.5091969). Such solid electrolytes are more environmentally friendly than traditional liquid electrolytes and could make lithium-ion batteries significantly safer and more efficient.

Researchers from the Fraunhofer Institute for Mechanics of Materials IWM have developed a new process that can bend sheets of glass to produce angular corners. Unlike conventional processes, this does not impair the optical properties of the glass. Bent glass looks destined to play a key role in future building design, and there are also potential applications in the fields of medical technology and industrial design.

Polyethylene (PE) would be an ideal material for lightweight construction: energy-efficient, can be produced from renewable raw materials, almost residue-free recyclable. However, only PE components that are reinforced as composites for example with carbon or glass fibers are truly mechanically resilient. Scientists at the Fraunhofer IWM, MicroTribology Centrum µTC, together with the Freiburg Materials Research Centre and the polyolefin manufacturer LyondellBasell, have now produced and qualified a sustainable "All-PE composite". The trick is that the reinforcing fiber structures are also made of PE and even form themselves during injection molding.

How will scientific work and product development evolve in the future? How will we share new insights with colleagues, who might work on the other side of the planet? Funded by the German Federal Ministry for Education and Research, the joint project »Innovation Platform MaterialDigitial« has recently been established to pave the way towards a digital infrastructure for material science research data. The objective is to create a virtual materials data space that allows a systematic handling of materials data.

Machine bearings are usually lubricated with various oils. But today large quantities of these oils still end up in the environment. The Fraunhofer Institute for Mechanics of Materials IWM, MicroTribology Centrum μTC has developed a method which will in the future make it possible to lubricate slide bearings using water, a much more environmentally friendly approach.

Natural rubber from rubber trees is a raw material with a limited supply. Synthetically produced rubber, on the other hand, has not yet been able to match the abrasion behavior of the natural product, rendering it unsuitable for truck tires. But now, for the first time, a new type of synthetic rubber has been developed that achieves 30 to 50 percent less abrasion than natural rubber.

On April 1, 2019, the Fraunhofer-Gesellschaft launches the lighthouse project »Quantum Magnetometry« (QMag): Freiburg’s Fraunhofer institutes IAF, IPM and IWM aim to transfer quantum magentometry from the field of university research to industrial applications. In close cooperation with another three Fraunhofer institutes (IMM, IISB and CAP), the research team develops highly integrated imaging quantum magnetometers with highest spatial resolution and sensitivity.

The phenomenon of so-called superlubricity is known, but so far the explanation at the atomic level has been missing: for example, how does extremely low friction occur in bearings? Researchers from the Fraunhofer Institutes IWM and IWS jointly deciphered a universal mechanism of superlubricity for certain diamond-like carbon layers in combination with organic lubricants. Based on this knowledge, it is now possible to formulate design rules for supra lubricating layer-lubricant combinations. The results are presented in an article in Nature Communications, volume 10.

To ensure the digital networking of production systems and the optimization of material-specific requirements, we need to measure, analyze and replicate the changes in material properties in a process in which “digital twins” of materials are created. The materials data space developed by Fraunhofer researchers has laid the groundwork for this process.

Permanent magnets used in electric cars and wind turbines currently contain rare earth metals. Reducing the amount of these elements in magnets is important, as mining them is harmful both to health and the environment. Researchers have now developed a new machine learning tool to assist in quickly and easily predicting the ferromagnetic crystal properties of novel material compositions.