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Correlating topographic features and mechanisms for macropitting, micropitting, and electrical pitting in bearing steel contacts

Correlating topographic features and mechanisms for macropitting, micropitting, and electrical pitting in bearing steel contacts
Correlating topographic features and mechanisms for macropitting, micropitting, and electrical pitting in bearing steel contacts
Pitting is a critical damage mode in rolling–sliding contacts that can arise from distinct mechanisms, including rolling contact fatigue and electrically induced discharge. This paper presents insights into the formation and characteristics of macropitting, micropitting, and electrical pitting in rolling–sliding contacts of bearing steels. Experiments were conducted using a TE74 twin-disc tribometer under controlled lubrication and electrical conditions. Under boundary to mixed lubrication, macropitting and micropitting were generated using a base oil and a ZDDP-enriched oil, respectively. Electrical pitting was produced by applying a low electrical potential across the lubricated contact under elastohydrodynamic lubrication conditions.
The three pitting modes exhibited distinct pit morphologies, crack features, and surface topography evolution. Macropitting was characterised by large, irregular pits formed through aggressive secondary crack propagation, whereas micropitting produced smaller, crescent-shaped pits with limited crack growth. Electrical pitting resulted in near-circular pits without surrounding cracks, indicating a discharge-dominated damage mechanism. Roughness parameters also revealed mechanism-dependent surface modifications, providing a unified topography-based framework for differentiating fatigue-driven and electrically induced pitting.
macropitting, micropitting, electrical pitting, rolling-sliding contact, surface topography
2051-672X
Tian, Zaihao
6c5ef4d8-60aa-4615-910e-b47954e322e8
Harvey, Terence
3b94322b-18da-4de8-b1af-56d202677e04
Zhuo, Shifeng
0ce1fe89-8501-4600-9948-627aa30b2ce3
Pan, Haidong
4e5fcea1-b0a1-4b1e-9eed-8cfee7ddd0eb
Wood, Robert
d9523d31-41a8-459a-8831-70e29ffe8a73
Tian, Zaihao
6c5ef4d8-60aa-4615-910e-b47954e322e8
Harvey, Terence
3b94322b-18da-4de8-b1af-56d202677e04
Zhuo, Shifeng
0ce1fe89-8501-4600-9948-627aa30b2ce3
Pan, Haidong
4e5fcea1-b0a1-4b1e-9eed-8cfee7ddd0eb
Wood, Robert
d9523d31-41a8-459a-8831-70e29ffe8a73

Tian, Zaihao, Harvey, Terence, Zhuo, Shifeng, Pan, Haidong and Wood, Robert (2026) Correlating topographic features and mechanisms for macropitting, micropitting, and electrical pitting in bearing steel contacts. Surface Topography: Metrology and Properties, 14 (2), [025005]. (doi:10.1088/2051-672X/ae5f36).

Record type: Article

Abstract

Pitting is a critical damage mode in rolling–sliding contacts that can arise from distinct mechanisms, including rolling contact fatigue and electrically induced discharge. This paper presents insights into the formation and characteristics of macropitting, micropitting, and electrical pitting in rolling–sliding contacts of bearing steels. Experiments were conducted using a TE74 twin-disc tribometer under controlled lubrication and electrical conditions. Under boundary to mixed lubrication, macropitting and micropitting were generated using a base oil and a ZDDP-enriched oil, respectively. Electrical pitting was produced by applying a low electrical potential across the lubricated contact under elastohydrodynamic lubrication conditions.
The three pitting modes exhibited distinct pit morphologies, crack features, and surface topography evolution. Macropitting was characterised by large, irregular pits formed through aggressive secondary crack propagation, whereas micropitting produced smaller, crescent-shaped pits with limited crack growth. Electrical pitting resulted in near-circular pits without surrounding cracks, indicating a discharge-dominated damage mechanism. Roughness parameters also revealed mechanism-dependent surface modifications, providing a unified topography-based framework for differentiating fatigue-driven and electrically induced pitting.

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More information

Accepted/In Press date: 20 March 2026
e-pub ahead of print date: 23 April 2026
Published date: 23 April 2026
Keywords: macropitting, micropitting, electrical pitting, rolling-sliding contact, surface topography

Identifiers

Local EPrints ID: 511183
URI: http://eprints.soton.ac.uk/id/eprint/511183
DOI: doi:10.1088/2051-672X/ae5f36
ISSN: 2051-672X
PURE UUID: aa429714-95ea-4663-a5a8-91ddd15f2470
ORCID for Terence Harvey: ORCID iD orcid.org/0000-0001-6596-5565
ORCID for Robert Wood: ORCID iD orcid.org/0000-0003-0681-9239

Catalogue record

Date deposited: 06 May 2026 16:33
Last modified: 07 May 2026 01:36

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Contributors

Author: Zaihao Tian
Author: Terence Harvey ORCID iD
Author: Shifeng Zhuo
Author: Haidong Pan
Author: Robert Wood ORCID iD

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