Abstract
Electron emission (EE) from real metal surfaces occurring during sliding contact with a polytetrafluoroethylene (PTFE) rider has been investigated using the thermodynamic data of metal oxides and the X-ray photoelectron spectroscopy (XPS) intensity ratio of oxygen/metal on the surfaces. EE was termed triboelectron emission (TriboEE). Rolled metal sheets of 18 types were used. The metal‒oxygen bond energy calculated from the heat of the formation of metal oxide, (D(M–O)), was shown to be a key factor in dividing the EE into two routes, the so-called Schottky effect and the tunnel effect, due to the surface oxide layer. The metals in periodic groups 4 (Ti and Zr), 5 (V, Nb, and Ta), and 6 (Mo and W) maintained higher values of D(M–O), while, moving down the groups, the TriboEE intensity increased, being ascribed to the former route. In groups 10 (Ni, Pd, and Pt) and 11 (Cu, Ag, and Au), the D(M–O) values decreased moving down the groups, but the TriboEE intensity increased significantly, which can be attributed to the latter route. Furthermore, with the increase in the electrical conductivity of metals, the TriboEE intensity became remarkably high, while the D(M–O) value fell rapidly and became almost constant. The XPS results showed that the dependence of the D(M–O) and XPS metal core intensity on the O1s intensity and the XPS intensity ratio of the O1s/metal core was different between groups 10 and 11 and groups 4, 5, and 6. It was concluded that, under the electric field caused on the real metal surface by the friction with PTFE, the electron from metals with small D(M–O) values predominantly tunnels the surface oxide layer as a surface barrier, while with large D(M–O) values, the electron passes over the top of the barrier.
Highlights
The information on the properties of electrons at metal surfaces involved in the interaction with environments has been of much interest in fields such as adhesion, coating, corrosion, and catalysis [1,2,3]
We explained that triboelectron emission (TriboEE) may be associated with the release of electrons transported to the attached PTFE debris from the metal substrate by a surface electric field occurring during the sliding
The main conclusion we reached was that the increase in TriboEE intensity between two adjoining metals in the same period correlated to a decrease in the work function (WF) or phototheshold values of metal samples; for the metals in groups 4, 5, and 6, moving down the groups of the periodic table, the increase in TriboEE intensity was related to a decrease in the WF and photothreshold values, but with the metals in groups 10 and 11, this relationship could not be confirmed
Summary
The information on the properties of electrons at metal surfaces involved in the interaction with environments has been of much interest in fields such as adhesion, coating, corrosion, and catalysis [1,2,3]. We reported the total number of electrons emitted from commercial rolled metal sheets of 18 kinds during sliding contact with a polytetrafluoroethylene (PTFE) rider for 60 min and its relationship with the X-ray photoelectron spectroscopy (XPS) results [7,8]. In these reports, the EE and the total number of emitted electrons were termed tribostimulated electron emissions or triboelectron emissions (TriboEE), and TriboEE total count or TriboEE intensity. The main conclusion we reached was that the increase in TriboEE intensity between two adjoining metals in the same period correlated to a decrease in the WF or phototheshold values of metal samples; for the metals in groups 4, 5, and 6, moving down the groups of the periodic table, the increase in TriboEE intensity was related to a decrease in the WF and photothreshold values, but with the metals in groups 10 and 11, this relationship could not be confirmed
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