AI Article Synopsis
- Lattice thermal conductivity is essential for managing heat in electronic devices, and this study focuses on monolayer fluorinated graphene's thermal properties using advanced computational techniques.
- At 300 K, chair-configured fluorinated graphene shows higher thermal conductivity (184.24 W/mK zigzag, 205.57 W/mK armchair) compared to boat-configured (120.45 W/mK zigzag, 64.26 W/mK armchair).
- The differences in thermal conductivity between configurations are mainly due to phonon relaxation times and stronger in-plane carbon-carbon bonds in the chair configuration, which influence the material's anharmonicity.
Article Abstract
Lattice thermal conductivity () plays a crucial role in the thermal management of electronic devices. In this study, we systematically investigate the thermal transport properties of monolayer fluorinated graphene using a combination of machine learning-based interatomic potentials and the phonon Boltzmann transport equation. At a temperature of 300 K, we find that the values for chair-configured fluorinated graphene monolayers are 184.24 W m K in the zigzag direction and 205.57 W m K in the armchair direction. For the boat configuration, the values are 120.45 W m K and 64.26 W m K in the respective directions. The disparities in between these two configurations predominantly stem from differences in phonon relaxation times, which can be elucidated by examining the Grüneisen parameters representing the degree of anharmonicity. A more in-depth analysis of bond strengths, as assessed by the crystal orbital Hamiltonian population, reveals that the stronger in-plane CC bonds in chair-configured fluorinated graphene monolayers are the primary contributors to the observed variations in anharmonicity.
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| http://dx.doi.org/10.1039/d3cp04923j | DOI Listing |
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