B. Gleising scite author profile

To control and minimize wear of metal-on-metal hip joints it is essential to understand the mechanisms of debris generation. In vivo, mainly nanosize globular and needle-shaped particles are found. These can neither stem from the action of abrasion nor from tribochemical reactions. In this study the acting wear mechanisms have been first identified on the surface by means of scanning electron microscopy (SEM). Afterwards, the microstructures of the subsurface regions of explants have been investigated using a transmission electron microscope (TEM). Observation of the subsurface gave additional insight about the microstructural changes of cobalt-base alloys subjected to wear. At some distance from the surface, a network of stacking faults and hexagonal ⑀-martensite was found strengthening the bulk material. This microstructure changed into a nanocrystalline type moving closer towards the surface. A comparison of in vivo debris size and grain size of the surface suggests that the globular wear particles result from torn off nanocrystals, while the needle shaped particles are generated by fractured ⑀-martensite. Identified cracks, propagating through the nanocrystalline layer, further support these findings. Thus, it is suggested that the dominating mechanism of particle generation for metal-on-metal joints is surface fatigue within a nanocrystalline surface layer.

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Microstructure of tribologically induced nanolayers produced at ultra-low wear rates

Shakhvorostov

Gleising

Büscher

et al. 2007

Wear

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Subsurface changes of a MoM hip implant below different contact zones

Pourzal¹,

Theissmann²,

Williams³

et al. 2009

Journal of the Mechanical Behavior of Biomedical Materials

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The role of process temperature and rotational speed in the microstructure evolution of Ti-6Al-4V friction surfacing coatings

et al. 2016

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The effects of subsurface deformation on the sliding wear behaviour of a microtextured high-nitrogen steel surface

Büscher

Gleising

Dudziński

et al. 2004

Wear

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B. Gleising

Subsurface microstructure of metal‐on‐metal hip joints and its relationship to wear particle generation

Microstructure of tribologically induced nanolayers produced at ultra-low wear rates

Subsurface changes of a MoM hip implant below different contact zones

The role of process temperature and rotational speed in the microstructure evolution of Ti-6Al-4V friction surfacing coatings

The effects of subsurface deformation on the sliding wear behaviour of a microtextured high-nitrogen steel surface

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