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Abstract
Dissipative particle dynamics with energy conservation (eDPD) was applied to conduction heat transfer in two-dimensional domains. The ability of the eDPD approach to simulate heat conduction in two-dimensional domains was tested by implementing various types of boundary conditions. The boundary conditions used in the present study are a combination of constant temperature, constant heat flux, adiabatic, and convective heat transfer. Furthermore, the eDPD approach was extended to study two-dimensional conduction with internal heat generation. This problem was further used to calculate the thermal diffusivity of the two-dimensional eDPD system. The eDPD simulations were compared to analytical and finite-difference solutions. The simulations show that the eDPD approach properly calculated the temperature distribution in the conduction domain.
The author would like to thank the Alexander von Humboldt Foundation (AvH) for supporting his research stay at the Leibniz Universität Hannover. Also, the author would like to thank the Arab Fund for Economic and Social Development in Kuwait, and Professor M. Faghri at the University of Rhode Island.
