Chemical nature of alkaline polyphosphate boundary film at heated rubbing surfaces

Shanhong Wan; A. Kiet Tieu; Qiang Zhu; Hongtao Zhu; Shaogang Cui; David R. G. Mitchell; Charlie Kong; Bruce Cowie; John A. Denman; Rong Liu

doi:10.1038/srep26008

Chemical nature of alkaline polyphosphate boundary film at heated rubbing surfaces

Shanhong Wan, A. Kiet Tieu, Qiang Zhu, Hongtao Zhu, Shaogang Cui, David R. G. Mitchell, Charlie Kong, Bruce Cowie, John A. Denman, Rong Liu

Western Sydney University

Research output: Contribution to journal › Article › peer-review

32 Citations (Scopus)

Abstract

Alkaline polyphosphate has been demonstrated to be able to reduce significant wear and friction of sliding interfaces under heavy loads (>1"‰GPa) and elevated temperature (800"‰Ã‚Â°C and above) conditions, e.g. hot metal manufacturing. The chemical composition and fine structure of polyphosphate lubricating film is not well understood as well as the role of alkaline elements within the reaction film at hot rubbing surface. This work makes use of the coupling surface analytical techniques on the alkaline polyphosphate tribofilm, XANES, TOF-SIMS and FIB/TEM. The data show the composition in gradient distribution and trilaminar structure of tribofilm: a shorter chain phosphate overlying a long chain polyphosphate that adheres onto oxide steel base through a short chain phosphate. The chemical hardness model well explains the anti-abrasive mechanism of alkaline polyphosphate at elevated temperatures and also predicts a depolymerisation and simultaneous cross-linking of the polyphosphate glass. The role of alkaline elements in the lubrication mechanism is especially explained. This work firstly serves as a basis for a detailed study of alkaline polyphosphate tribofilm at temperature over 600"‰Ã‚Â°C.

Original language	English
Article number	26008
Number of pages	16
Journal	Scientific Reports
Volume	6
DOIs	https://doi.org/10.1038/srep26008
Publication status	Published - 2016

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Keywords

chemicals
molecules

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10.1038/srep26008

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title = "Chemical nature of alkaline polyphosphate boundary film at heated rubbing surfaces",

abstract = "Alkaline polyphosphate has been demonstrated to be able to reduce significant wear and friction of sliding interfaces under heavy loads (>1{"}‰GPa) and elevated temperature (800{"}‰{\~A}‚{\^A}°C and above) conditions, e.g. hot metal manufacturing. The chemical composition and fine structure of polyphosphate lubricating film is not well understood as well as the role of alkaline elements within the reaction film at hot rubbing surface. This work makes use of the coupling surface analytical techniques on the alkaline polyphosphate tribofilm, XANES, TOF-SIMS and FIB/TEM. The data show the composition in gradient distribution and trilaminar structure of tribofilm: a shorter chain phosphate overlying a long chain polyphosphate that adheres onto oxide steel base through a short chain phosphate. The chemical hardness model well explains the anti-abrasive mechanism of alkaline polyphosphate at elevated temperatures and also predicts a depolymerisation and simultaneous cross-linking of the polyphosphate glass. The role of alkaline elements in the lubrication mechanism is especially explained. This work firstly serves as a basis for a detailed study of alkaline polyphosphate tribofilm at temperature over 600{"}‰{\~A}‚{\^A}°C.",

keywords = "chemicals, molecules",

author = "Shanhong Wan and Tieu, {A. Kiet} and Qiang Zhu and Hongtao Zhu and Shaogang Cui and Mitchell, {David R. G.} and Charlie Kong and Bruce Cowie and Denman, {John A.} and Rong Liu",

year = "2016",

doi = "10.1038/srep26008",

language = "English",

volume = "6",

journal = "Scientific Reports",

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TY - JOUR

T1 - Chemical nature of alkaline polyphosphate boundary film at heated rubbing surfaces

AU - Wan, Shanhong

AU - Tieu, A. Kiet

AU - Zhu, Qiang

AU - Zhu, Hongtao

AU - Cui, Shaogang

AU - Mitchell, David R. G.

AU - Kong, Charlie

AU - Cowie, Bruce

AU - Denman, John A.

AU - Liu, Rong

PY - 2016

Y1 - 2016

N2 - Alkaline polyphosphate has been demonstrated to be able to reduce significant wear and friction of sliding interfaces under heavy loads (>1"‰GPa) and elevated temperature (800"‰Ã‚Â°C and above) conditions, e.g. hot metal manufacturing. The chemical composition and fine structure of polyphosphate lubricating film is not well understood as well as the role of alkaline elements within the reaction film at hot rubbing surface. This work makes use of the coupling surface analytical techniques on the alkaline polyphosphate tribofilm, XANES, TOF-SIMS and FIB/TEM. The data show the composition in gradient distribution and trilaminar structure of tribofilm: a shorter chain phosphate overlying a long chain polyphosphate that adheres onto oxide steel base through a short chain phosphate. The chemical hardness model well explains the anti-abrasive mechanism of alkaline polyphosphate at elevated temperatures and also predicts a depolymerisation and simultaneous cross-linking of the polyphosphate glass. The role of alkaline elements in the lubrication mechanism is especially explained. This work firstly serves as a basis for a detailed study of alkaline polyphosphate tribofilm at temperature over 600"‰Ã‚Â°C.

AB - Alkaline polyphosphate has been demonstrated to be able to reduce significant wear and friction of sliding interfaces under heavy loads (>1"‰GPa) and elevated temperature (800"‰Ã‚Â°C and above) conditions, e.g. hot metal manufacturing. The chemical composition and fine structure of polyphosphate lubricating film is not well understood as well as the role of alkaline elements within the reaction film at hot rubbing surface. This work makes use of the coupling surface analytical techniques on the alkaline polyphosphate tribofilm, XANES, TOF-SIMS and FIB/TEM. The data show the composition in gradient distribution and trilaminar structure of tribofilm: a shorter chain phosphate overlying a long chain polyphosphate that adheres onto oxide steel base through a short chain phosphate. The chemical hardness model well explains the anti-abrasive mechanism of alkaline polyphosphate at elevated temperatures and also predicts a depolymerisation and simultaneous cross-linking of the polyphosphate glass. The role of alkaline elements in the lubrication mechanism is especially explained. This work firstly serves as a basis for a detailed study of alkaline polyphosphate tribofilm at temperature over 600"‰Ã‚Â°C.

KW - chemicals

KW - molecules

UR - http://handle.uws.edu.au:8081/1959.7/uws:35690

U2 - 10.1038/srep26008

DO - 10.1038/srep26008

M3 - Article

SN - 2045-2322

VL - 6

JO - Scientific Reports

JF - Scientific Reports

M1 - 26008

ER -

Chemical nature of alkaline polyphosphate boundary film at heated rubbing surfaces

Abstract

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Keywords

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