Abstract
An off-lattice Monte Carlo model was developed to study the heat transfer in three-phase systems containing carbon nanotubes (CNTs) randomly orientated and distributed at the interface of another two media. Thermal energy was simulated by a large number of discrete thermal walkers with a random movement in the CNTs and a Brownian motion in the other two media. Thermal boundary resistances (TBRs) were calculated according to the Acoustic Mismatch theory and were applied in the simulation using the probabilities of the thermal walkers to travel across the interfaces. The numerical models were validated by comparing the simulation results with the theoretically calculated values for a spherical heat source. Using the current model, heat transfer properties with complex morphology of CNTs (diameter, orientations, and aspect ratio), as well as different heat sources, can be quantified.
Notes
To quantify all the parameters in our model, a real case of the cancer treatment is applied. We consider a cancer cell in a cubic tissue box and the CNTs are randomly orientated and distributed on the cancer cell surface, so the parameters of medium 1 are taken from the human tissue and those of the medium 2 are taken from cancer cell.
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