Title :
The Viscoelastic Behavior of Perfluoropolyether Lubricants
Author :
Guo, Qian ; Jhon, Myung S.
Author_Institution :
Dept. of Chem. Eng., Carnegie Mellon Univ., Pittsburgh, PA
Abstract :
Molecular rheology of perfluoropolyether (PFPE) systems can be particularly important in designing effective lubricants that control the friction and wear in their tribological applications. Using equilibrium/nonequilibrium molecular dynamics simulation, we examined the viscoelastic properties of PFPE melts under oscillatory shear, such as dynamic moduli and viscosity, by monitoring the time-dependent strain-stress curve. Strong dependences of PFPE melt viscoelasticity on molecular architecture (e.g., endgroup functionality) and external conditions (e.g., temperature and oscillation frequency) were observed. Nonfunctional PFPEs exhibit liquid-like behavior, while "pseudoreptation-like" behavior is captured for functional PFPEs, where endgroup couplings are found to be dissociated at high temperatures. The empirical Cox-Merz rule was also discussed
Keywords :
hard discs; lubricants; magnetic recording; magnetorheology; molecular dynamics method; polymer melts; stress-strain relations; viscoelasticity; PFPE melts; dynamic moduli; dynamic viscosity; empirical Cox-Merz rule; endgroup couplings; liquid-like behavior; molecular dynamics simulation; molecular rheology; oscillatory shear; perfluoropolyether lubricants; pseudoreptation-like behavior; strain-stress curve; viscoelastic behavior; Capacitive sensors; Chemical engineering; Elasticity; Equations; Frequency; Lubricants; Lubrication; Rheology; Stress; Viscosity; Cox–Merz rule; dynamic moduli; dynamic viscosity; viscoelasticity;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2006.878649
