Molecular modeling and electron transport in polyethylene

Wang, Yang; Wu, Kai; Cubero, David; Quirke, N.

doi:10.1109/tdei.2014.004387

Cited by 4 publications

(4 citation statements)

References 63 publications

(89 reference statements)

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“…In case of polyethylene, where charge transport dynamics through disordered molecular conformations has been studied in details, the presence of localized regions of free volume has been shown to be an important factor in electronic conduction. [40][41][42] Finally, the presence of GHE modifies the viscosity of the reacting system prior to vitrification; while the measured viscosity at 20 °C of the neat epoxy was 0.266±(4x10 -4 ) Pa.s, this figure was reduced to 0.101±(4x10 -4 ) Pa.s for 30GHE. As such, the presence of GHE would be expected to increase somewhat the efficiency of cross-linking, thereby affecting the residual unreacted end groups that remain within the network, another factor that has been shown to be important in determining the electrical behaviour of epoxy resins.…”

Section: Conductivity Of Ghe-modified Systemsmentioning

confidence: 95%

“…Second, the introduction of the GHE modifier produces a network system containing alkyl branches which, based upon the observed reduction in T g , leads to increased free volume. In case of polyethylene, where charge transport dynamics through disordered molecular conformations has been studied in details, the presence of localized regions of free volume has been shown to be an important factor in electronic conduction [40][41][42]. Finally, the presence of GHE modifies the viscosity of the reacting system prior to vitrification; while the measured viscosity at 20 °C of the neat epoxy was 0.266 ± (4 × 10 −4 ) Pa.s, this figure was reduced to 0.101 ± (4 × 10 −4 ) Pa.s for 30GHE.…”

Section: Thermal Measurements Of Ghe-modified Systemsmentioning

confidence: 99%

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Functional design of epoxy-based networks: tailoring advanced dielectrics for next-generation energy systems

Saeedi¹,

Vaughan²,

Andritsch³

2019

J. Phys. D: Appl. Phys.

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Epoxy resins are widely used as the primary insulation material in many demanding energyrelated applications. As such, the ability specifically to tailor the electrical performance of such systems to meet increasingly demanding insulation situations has considerable utility. This paper describes a new approach to this problem, which is based upon the controlled introduction of specific functional groups into the cured resin's network architecture. Here, two additives are considered, termed functional network modifiers (FNM), namely glycidyl hexadecyl ether and glycidyl 4-nonylphenyl ether; in all the investigated systems, the ideal stoichiometric ratio of epoxide groups to amine hydrogens is retained. In the case of both FNM, their inclusion resulted in a progressive reduction in the glass transition temperature T g of the system, a reduction in the real part of the permittivity and reduced dielectric losses wihin the accessible frequency range, increased DC conductivity and increased AC breakdown strength. The magnitude of the observed effects are found to be dependent upon the choice of functional modifier, which suggests that such changes are not related merely to the inclusion of an additive within the system, but are also influenced by the chemistry of the additive itself. Explanations for these effects are proposed. It is concluded that the use of such FNM at low concentrations (~4% in the work reported here) offers a novel alternative means of engineering advanced materials to meet the current and future needs in an adaptable and easily implemented manner.

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Section: Conductivity Of Ghe-modified Systemsmentioning

confidence: 95%

Section: Thermal Measurements Of Ghe-modified Systemsmentioning

confidence: 99%

Functional design of epoxy-based networks: tailoring advanced dielectrics for next-generation energy systems

Saeedi¹,

Vaughan²,

Andritsch³

2019

J. Phys. D: Appl. Phys.

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“…Direct measurements and simulations show that polyethylene has multi-levels of traps (identified as chemical and physical in their nature) which limit the charge transport [20,21]. The physical traps are formed by the disorder of the chain structure and local morphology [21,22]. Those traps together control the apparent charge mobility [20][21][22].…”

Section: Influence Of Reduced Activation Energymentioning

confidence: 99%

“…The physical traps are formed by the disorder of the chain structure and local morphology [21,22]. Those traps together control the apparent charge mobility [20][21][22]. The electric field assisted chain movement is regarded as opening traps down to a certain depth.…”

Section: Influence Of Reduced Activation Energymentioning

confidence: 99%

A model and simulation of fast space charge pulses in polymers

Rowland

2017

J. Phys. D: Appl. Phys.

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The transport of space charge packets across polyethylene and epoxy resin in high electric fields has been characterized as fast or slow depending on packet mobility. Several explanations for the formation and transport of slow space charge packets have been proposed, but the origins of fast space charge pulses, with mobilities above 10−11 m2 V−1 s−1, are unclear. In one suggested model, it is assumed that the formation of fast charge pulses is due to discontinuous electromechanical compression and charge injection at the electrode-insulation interface, and their transport is related to corresponding relaxation processes. In that model, charges travel as a pulse because of group polarization. This paper provides an alternative model based on the reduction of charge carrier activation energy due to charge density triggered polymer chain movement and subsequent chain relaxation times. The generation and transport of fast charge pulses are readily simulated by a bipolar charge transport model with three additional parameters: reduced activation energy, charge density threshold, and chain relaxation time. Such a model is shown to reproduce key features of fast space charge pulses including speed, duration, repetition rate and pulse size. This model provides the basis for a deep understanding of the physical origins of fast space charge pulses in polymers.

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