Abstract
In order to increase our fundamental knowledge about high-voltage cable insulation materials, realistic polyethylene (PE) structures, generated with a novel molecular modeling strategy, have been analyzed using first principle electronic structure simulations. The PE structures were constructed by first generating atomistic PE configurations with an off-lattice Monte Carlo method and then equilibrating the structures at the desired temperature and pressure using molecular dynamics simulations. Semicrystalline, fully crystalline and fully amorphous PE, in some cases including crosslinks and short-chain branches, were analyzed. The modeled PE had a structure in agreement with established experimental data. Linear-scaling density functional theory (LS-DFT) was used to examine the electronic structure (e.g., spatial distribution of molecular orbitals, bandgaps and mobility edges) on all the materials, whereas conventional DFT was used to validate the LS-DFT results on small systems. When hybrid functionals were used, the simulated bandgaps were close to the experimental values. The localization of valence and conduction band states was demonstrated. The localized states in the conduction band were primarily found in the free volume (result of gauche conformations) present in the amorphous regions. For branched and crosslinked structures, the localized electronic states closest to the valence band edge were positioned at branches and crosslinks, respectively. At 0 K, the activation energy for transport was lower for holes than for electrons. However, at room temperature, the effective activation energy was very low (∼0.1 eV) for both holes and electrons, which indicates that the mobility will be relatively high even below the mobility edges and suggests that charge carriers can be hot carriers above the mobility edges in the presence of a high electrical field.
Highlights
Polyethylene (PE) is currently used as the preferred electrical insulation material in extruded high voltage cables
The initial semicrystalline PE structures were constructed with a Monte Carlo (MC) phantom-chain model and were subsequently equilibrated with molecular dynamics (MD)
The conduction band states were localized in the free volume of the non-crystalline parts
Summary
Polyethylene (PE) is currently used as the preferred electrical insulation material in extruded high voltage cables. The transport of electrical energy over a long distance (e.g., in inter-continental grids) requires a very high voltage in order to achieve acceptable levels of energy loss. The electrical and thermal stresses on the insulation materials increase with increasing voltage. It is crucial to improve the insulation materials, by optimizing the electrical conductivity, thermal conductivity, dielectric permittivity, and electrical breakdown strength.. First principle simulations can provide a better fundamental understanding of the macroscopic electrical properties, which is valuable when optimizing the material. This paper concerns the modeling of realistic polyethylene systems (amorphous, crystalline, semicrystalline, branched, and crosslinked) and first principle simulations of those systems
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