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Exploring the interactions of ZDDP additive with hematite surfaces: a DFT+U study

Exploring the interactions of ZDDP additive with hematite surfaces: a DFT+U study
Exploring the interactions of ZDDP additive with hematite surfaces: a DFT+U study
The class of zinc dialkyldithiophosphates (ZDDPs) has been the most widely used anti-wear additive class in the automotive industry for over 60 years, yet the pathway to the generation of the protective tribofilm remains elusive. In this context, density functional theory (DFT) can be utilized to investigate the interactions between ZDDPs and materials surfaces. We employed DFT+U calculations to examine the electronic structure of bulk hematite and three relevant (0001) surface terminations: Fe-O-Fe, O-Fe-Fe, and HO-Fe-Fe. Our results demonstrate that, while the Fe-O-Fe and HO-Fe-Fe slabs are insulating, the O-Fe-Fe terminated slab is metallic due to the formation of surface states from O dangling bonds. Additionally, we found that ZDDP binds more strongly on the Fe-O-Fe slab, leading to changes in ZDDP geometry and atomic charges. Minimal changes are observed when bound to the other surfaces. We have provided an in-depth study of the electronic structure of hematite and its surfaces, and their interaction with ZDDP. We include a detailed study of the first-principles Hubbard U and Hund J for Fe 3d orbitals in bulk hematite, finding a negligible self-consistency effect but a significant projector dependence. The new insights from this work provide a new path that can be used to understand the decomposition pathways of ZDDPs on metallic surfaces.
0953-8984
Sarpa, Davide
31529a89-8506-468b-88a2-16bf891e2dc5
O'Regan, David Daniel
f8da5224-8d54-4aa0-8fa7-dec9852799c6
Bakolas, Vasilios
15abf440-f075-4705-be98-39e110c33345
Procelewska, Joanna
1139b924-fc8c-413f-a970-7b21d1cc88c1
Franke, Joerg
dbd51038-392b-4fb8-b1a3-4934ce267545
Rödel, Philipp
6c874e27-9b5b-4fb8-86a9-88ad8339b1b8
Wolf, Marcus
0903c887-eefe-43f7-9173-efce9c865624
Skylaris, Chris
8f593d13-3ace-4558-ba08-04e48211af61
Sarpa, Davide
31529a89-8506-468b-88a2-16bf891e2dc5
O'Regan, David Daniel
f8da5224-8d54-4aa0-8fa7-dec9852799c6
Bakolas, Vasilios
15abf440-f075-4705-be98-39e110c33345
Procelewska, Joanna
1139b924-fc8c-413f-a970-7b21d1cc88c1
Franke, Joerg
dbd51038-392b-4fb8-b1a3-4934ce267545
Rödel, Philipp
6c874e27-9b5b-4fb8-86a9-88ad8339b1b8
Wolf, Marcus
0903c887-eefe-43f7-9173-efce9c865624
Skylaris, Chris
8f593d13-3ace-4558-ba08-04e48211af61

Sarpa, Davide, O'Regan, David Daniel, Bakolas, Vasilios, Procelewska, Joanna, Franke, Joerg, Rödel, Philipp, Wolf, Marcus and Skylaris, Chris (2025) Exploring the interactions of ZDDP additive with hematite surfaces: a DFT+U study. Journal of Physics: Condensed Matter, 37, [195502]. (doi:10.1088/1361-648X/adc5c2).

Record type: Article

Abstract

The class of zinc dialkyldithiophosphates (ZDDPs) has been the most widely used anti-wear additive class in the automotive industry for over 60 years, yet the pathway to the generation of the protective tribofilm remains elusive. In this context, density functional theory (DFT) can be utilized to investigate the interactions between ZDDPs and materials surfaces. We employed DFT+U calculations to examine the electronic structure of bulk hematite and three relevant (0001) surface terminations: Fe-O-Fe, O-Fe-Fe, and HO-Fe-Fe. Our results demonstrate that, while the Fe-O-Fe and HO-Fe-Fe slabs are insulating, the O-Fe-Fe terminated slab is metallic due to the formation of surface states from O dangling bonds. Additionally, we found that ZDDP binds more strongly on the Fe-O-Fe slab, leading to changes in ZDDP geometry and atomic charges. Minimal changes are observed when bound to the other surfaces. We have provided an in-depth study of the electronic structure of hematite and its surfaces, and their interaction with ZDDP. We include a detailed study of the first-principles Hubbard U and Hund J for Fe 3d orbitals in bulk hematite, finding a negligible self-consistency effect but a significant projector dependence. The new insights from this work provide a new path that can be used to understand the decomposition pathways of ZDDPs on metallic surfaces.

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More information

Accepted/In Press date: 26 March 2025
e-pub ahead of print date: 17 April 2025
Learn more about School of Chemistry research Learn more about Institute for Life Sciences research Learn more about Institute for Life Sciences research

Identifiers

Local EPrints ID: 501394
URI: http://eprints.soton.ac.uk/id/eprint/501394
DOI: doi:10.1088/1361-648X/adc5c2
ISSN: 0953-8984
PURE UUID: a5037677-73c5-404e-895a-c6b1470ad685
ORCID for Chris Skylaris: ORCID iD orcid.org/0000-0003-0258-3433

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Date deposited: 30 May 2025 16:41
Last modified: 31 May 2025 01:41

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Contributors

Author: Davide Sarpa
Author: David Daniel O'Regan
Author: Vasilios Bakolas
Author: Joanna Procelewska
Author: Joerg Franke
Author: Philipp Rödel
Author: Marcus Wolf
Author: Chris Skylaris ORCID iD

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