Stress relief: Making materials crack-resistant
Wissenschaft, STRESS-SPEC |
In both industry and research, materials must meet a wide range of requirements. Scientists are therefore constantly searching for materials that are stronger, more durable, and more resistant to corrosion – so that ships, for instance, can withstand constant contact with salty water.
Reducing wear
The research team around Dr Michael Hofmann, instrument scientist at STRESS-SPEC at MLZ has investigated a specific composite material that can reduce wear. It consists of a metal alloy reinforced with tungsten carbide on the surface. “Tungsten carbide is almost as hard as diamond, making the materials particularly wear-resistant,” says Michael Hofmann. The tungsten carbide particles were delivered on the metal alloy substrate surface to form a composite coating with the help of laser heating. This manufacturing process is called laser melt injection. “This is a very industry-oriented application,” explains Dr Xingxing Zhang, “it concerns ship propellers, for example. If the coating breaks off, the material is damaged.” In other materials, tungsten carbide has already reduced wear by up to 80%.
Neutrons as the method of choice
The problem with the tested material currently lies in high internal stresses, so-called residual stresses of the material. These limit the performance and lifespan of the composite material. If ignored, they quickly lead to cracking, deformation and rapid fatigue. “We first tried X-raying the material,” explains Michael Hofmann. However, tungsten carbide proved too dense for this. “It allows hardly any radiation to pass through. Therefore, neutrons were essential.”
The researchers carried out the neutron measurements at the OPAL research reactor of the Australian Nuclear Science and Technology Organisation (ANSTO). They then used the scanning electron microscope at the Materials Science Lab at MLZ to resolve the material structure and distribution of the elements in detail. The scanning electron microscope is jointly operated by the Jülich Centre for Neutron Science and the Helmholtz-Zentrum hereon at the MLZ.
Heating leads to less stress
It turned out that heating the material could reduce internal stress. “In an industrial process, you don't want to have to go to the research reactor every time – you want a simulation that delivers reliable results,” says Michael Hofmann, “with our data, it’s possible to set up and validate such a model.”
Original publication:
X. X. Zhang, E. Walz, A. Langebeck, J. Rebelo Kornmeier, A. Kriele, V. Luzin, M. Adveev, A. Bohlen, M. Hofmann, Macroscopic and Microscopic Residual Stresses in Nickel‑Aluminum Bronze Matrix Composite Surface Deposits Manufactured via Laser Melt Injection. Acta Metallurgica Sinica (English Letters), Volume 38, 570 (2025). DOI: 10.1007/s40195-025-01829-x
More information:
In addition to scientists from TUM and FRM II, researchers from the Institute of High Energy Physics der Chinese Academy of Sciences, the Bremen Institute for Applied Beam Technology (BIAS), the German Engineering Materials Science Centre (GEMS) of the Helmholtz Centre Hereon, the Australian Nuclear Science and Technology Organisation (ANSTO) of the Australian Centre for Neutron Scattering, the School of Engineering at the University of Newcastle and the School of Chemistry at the University of Sydney have also contributed to this project.
Contact:
Dr. Michael Hofmann
Technical University of Munich
Instrument scientist at FRM II
E-Mail: michael.hofmann@frm2.tum.de
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