A thermodynamic model is developed for the melting of an ultrathin lubricant film squeezed between two atomically smooth solid surfaces. To describe the state of lubricant, an excess volume parameter is introduced; it appears due to the chaos in the structure of a solid body induced by melting. This parameter increases with the total internal energy upon melting. Thermodynamic melting and shear melting are described. The dependences of the friction force on the lubricant temperature and the shear rate of friction surfaces are analyzed. The calculated results are compared to the experimental data. When you are citing the document, use the following link http://essuir.sumdu.edu.ua/handle/123456789/1809
We represent a melting of ultrathin lubricant film by friction between atomically flat surfaces as ...
Melting of an ultrathin lubricant film during friction between atomically smooth surfaces is studied...
Using the Lorenz model for viscoelastic medium approximation the melting of ultrathin lubricant film...
A thermodynamic model is developed for the melting of an ultrathin lubricant film squeezed between t...
A deterministic theory describing the behavior of an ultrathin lubricant film between two atomically...
Melting of an ultrathin lubricant film confined between two atomically flat surfaces is studied. An ...
The thermodynamic model of ultrathin lubricant film melting, confined between two atomically-flat s...
The thermodynamic theory of thin lubricant film melting, confined between two hard rough solid surfa...
The melting of ultrathin lubricant film by friction between atomically flat surfaces is studied. Th...
The influence of a deformational defect of the shear modulus on the melting of an ultrathin lubrican...
The thermodynamic theory of thin lubricant film melting, confined between two hard rough solid surfa...
The melting of an ultrathin lubricant film is studied at friction between atomically flat surfaces...
We study the melting of ultrathin lubricant film under friction between atomically flat surfaces a...
Melting of an ultrafhin lubricant film under friction between atomically smooth surfaces is studied ...
The melting of an ultrathin lubricant film at friction between atomically smooth surfaces is studied...
We represent a melting of ultrathin lubricant film by friction between atomically flat surfaces as ...
Melting of an ultrathin lubricant film during friction between atomically smooth surfaces is studied...
Using the Lorenz model for viscoelastic medium approximation the melting of ultrathin lubricant film...
A thermodynamic model is developed for the melting of an ultrathin lubricant film squeezed between t...
A deterministic theory describing the behavior of an ultrathin lubricant film between two atomically...
Melting of an ultrathin lubricant film confined between two atomically flat surfaces is studied. An ...
The thermodynamic model of ultrathin lubricant film melting, confined between two atomically-flat s...
The thermodynamic theory of thin lubricant film melting, confined between two hard rough solid surfa...
The melting of ultrathin lubricant film by friction between atomically flat surfaces is studied. Th...
The influence of a deformational defect of the shear modulus on the melting of an ultrathin lubrican...
The thermodynamic theory of thin lubricant film melting, confined between two hard rough solid surfa...
The melting of an ultrathin lubricant film is studied at friction between atomically flat surfaces...
We study the melting of ultrathin lubricant film under friction between atomically flat surfaces a...
Melting of an ultrafhin lubricant film under friction between atomically smooth surfaces is studied ...
The melting of an ultrathin lubricant film at friction between atomically smooth surfaces is studied...
We represent a melting of ultrathin lubricant film by friction between atomically flat surfaces as ...
Melting of an ultrathin lubricant film during friction between atomically smooth surfaces is studied...
Using the Lorenz model for viscoelastic medium approximation the melting of ultrathin lubricant film...