Jm. Georges et al., FILM THICKNESS AND MECHANICAL-PROPERTIES OF ADSORBED NEUTRAL AND BASIC ZINC DIISOBUTYL DITHIOPHOSPHATES, Tribology transactions, 41(4), 1998, pp. 543-553
A surface force apparatus (SFA) has been used to determine film thickn
ess and film properties of adsorbed neutral and basic diisobutyl zinc
dithiophosphates (ZnDTPs) on cobalt surfaces. Sliding experiments were
also carried out and film characteristics determined after sliding. D
odecane was used as the solvent. Experiments with dodecane only show d
odecane molecules form an immobile monolayer on cobalt surfaces. When
subjected to sliding, this monolayer is displaced, and attractive forc
es between the cobalt surfaces are observed. Neither the films formed
initially upon adsorption of the ZnDTPs nor those films after sliding
are displaced by the tangential motion. After 80 nm of sliding, the co
efficient of friction was 1.2 in dodecane and 0.4 in the ZnDTP solutio
ns. Elastic compressive and shear moduli for the physisorbed ZnDTP fil
ms were similar to 0.1 GPa and 0.01-1 GPa, respectively. The distance
of first repulsion between the approaching surfaces corresponds roughl
y to two monolayers of ZnDTP on each surface. Under compression, ZnDTP
molecules that am not firmly bonded to the surface are expelled from
the contact. At 15-hour adsorption times for both ZnDTPs, the thicknes
s of the confined layer under load corresponds to one monomolecular la
yer separating the two surfaces. For the neutral ZnDTP, a monomolecula
r layer thickness is I nm and for basic ZnDTP it is 1.6 nm. A possible
explanation for a single molecular-layer separation is that the adsor
bed ZnDTP molecules are sparsely distributed on the surfaces, so spars
ely that when the surfaces approach the adsorbed molecules interleave
forming a layer of molecules of monomolecular thickness, of which some
are attached to one surface, and of which the remainder are attached
to the other surface. The SFA affords not only mechanical properties o
f thin films but also some information on their molecular structure.