Abstract
Graphene combined with fractal structures would probably be a promising candidate design of an antenna for a wireless communication system. However, the thermal transport properties of fractal graphene, which would influence the properties of wireless communication systems, are unclear. In this paper, the thermal transport properties of graphene with a Sierpinski fractal structure were investigated via the reverse non-equilibrium molecular dynamics simulation method. Simulation results indicated that the thermal conductivity of graphene with fractal defects decreased from 157.62 to 19.60 (W m−1 K−1) as the fractal level increased. Furthermore, visual display and statistical results of fractal graphene atomic heat flux revealed that with fractal levels increasing, the real heat flux paths twisted, and the angle distributions of atomic heat flux vectors enlarged from about (−30°, 30°) to about (−45°, 45°). In fact, the fractal structures decreased the real heat flow areas and extended the real heat flux paths, and enhanced the phonon scattering in the defect edges of the fractal graphene. Analyses of fractal graphene thermal transport characters in our work indicated that the heat transfer properties of fractal graphene dropped greatly as fractal levels increased, which would provide effective guidance to the design of antennae based on fractal graphene.
Highlights
The antenna is the fundamental component of transmitting and receiving radio waves in wireless communication systems, which restricts the performance and size of the wireless communication system
We investigated the thermal transport in length 21 nm × width 21 nm graphene with fractal defects in different levels, gra0, gra1, gra2, and gra3, using the reverse nonequilibrium molecular dynamics method (RNEMD) method
For gra0, its thermal conductivity is consistent with previous nanoribbon research [18]
Summary
The antenna is the fundamental component of transmitting and receiving radio waves in wireless communication systems, which restricts the performance and size of the wireless communication system. When the thermal transport into account to increase the reliability of the communication system That is, it is heat inside a high-power device cannot be released in time, the heat inside the device will cause necessary to study the thermal transportation properties of fractal graphene. Graphene with Sierpinski carpet fractal models with different fractal levels are microheat flux on each atom of these fractal graphene sheets is calculated and compared with perfect established, and their thermal conductivity and interfacial thermal resistances are calculated using graphene to verify the microscopic thermal transportation mechanism. The self-similar fractal dimension of the is as follows: Firstly, twice a square is cut into 9 congruent subsquares in a 3-by-3 grid, and theDcentral fractal structure is calculated by: subsquare is removed.
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