All-organic lead-free thermochromic and dielectric switchable epoxy microcomposites from singly incorporating leuco dye microcapsules for advanced encryption

Gao, Jian; Wu, Kangning; Li, Jianying; Yin, Gen; Li, Shengtao

doi:10.1088/1361-665x/acabef

Cited by 10 publications

(4 citation statements)

References 54 publications

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“…Under the action of oscillating magnetic field, these particles will gather around the tree channels in the material and repair the damage by heating, thus realizing the self‐healing of the material. This kind of intelligent insulating material should be paid attention to in future research [121]. In addition, partial discharge (PD) resistance, another important property for cable insulation, can also be enhanced by nano‐doping.…”

Section: Research Status Of Polypropylene Modification Based On Struc...mentioning

confidence: 99%

Eco‐friendly polypropylene power cable insulation: Present status and perspective

Yang

et al. 2023

IET Nanodielectrics

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Environmental protection is the future trend of power equipment development, and is also a research hotspot in the field of power cable insulation in recent years. Due to the excellent electrical properties and recyclability, polypropylene (PP) based composites are regarded as promising insulating materials for eco‐friendly next‐generation power cables. However, the high modulus and hardness of pure PP make it difficult to be directly employed as cable insulations, which needs to be further optimised. General methods of mechanical performance regulation often result in the deterioration of electrical performance, such as breakdown strength, space charge and so on. Therefore, it is recognised that the major challenge impeding practical applications of PP power cable insulation arises from the synergetic regulation of multi‐performances. The multi‐level structures influencing the multi‐performances of PP are introduced by the authors and the researches on the performance enhancement of PP through nanoscale structure regulation in recent years are reviewed in detail. Seven kinds of modification methods including nano‐doping, chemical grafting, in‐suit copolymerisation, heat treatment, nucleating agent, voltage stabiliser and elastomer blending are paid special attention. Based on the full understanding of the research status, the challenges and issues of future research are put forward for eco‐friendly PP power cable insulation.

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Section: Research Status Of Polypropylene Modification Based On Struc...mentioning

confidence: 99%

Eco‐friendly polypropylene power cable insulation: Present status and perspective

Yang

et al. 2023

IET Nanodielectrics

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“…Therefore, the new peaks can be ascribed to the relaxation of core materials in microsensors induced by the phase transition. As mentioned above, the solvents in microsensors will undergo the solid-liquid phase transition from approximately 48 • C to 66 • C, wherein the molecules of core materials are gradually liberated with enhanced intermolecular distances and mobility, facilitating the reorientation and transport of core materials within the microsensors and resulting in the interfacial relaxations, namely the Maxwell-Wagner relaxations [51], at the inner surfaces of microsensor encapsulation [52]. Accordingly, the relaxation peak temperature in different SRDs should be identical, and the relaxation strength should gradually increase with the microsensor content since the relaxation processes occur inside the microsensors, verifying the above analysis.…”

Section: Role Of Microsensor Encapsulation On the Electrical Properti...mentioning

confidence: 99%

Endowing smart self-reporting epoxy composites with superior electrical properties from ultralow-content electron-donating encapsulated microsensors

Gao

Zhang

et al. 2023

J. Phys. D: Appl. Phys.

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Smart self-reporting dielectrics (SRDs) have been extensively utilized for intelligentizing and miniaturizing the next-generation advanced electrical and electronic devices. However, the switchable structures toward the self-reporting function commonly injure electrical properties, severely undermining the reliability and practicality of SRDs. Herein, the smart self-reporting function and superior electrical properties are simultaneously achieved singly through incorporating ultralow content microsensors with electron-donating encapsulation into the epoxy matrix. The microsensor is a leuco dye system for self-reporting temperature anomalies through thermochromism. The strong electron-donating melamine–formaldehyde encapsulation of microsensors serves to confine the switchable structures and enhance electrical properties by constructing the interfacial barrier effect through triboelectrification. Under an ultralow doping content of 0.5phr, the electrical conductivity of SRDs is considerably reduced by about 80% at the elevated temperature of 80 °C compared to that of the widely recognized epoxy insulation. The reduction efficiency is far superior to those of numerous micro- and nanofillers. The interfacial barrier effect could be supported by the significantly reduced trapped charge density and trap levels in SRDs based on thermal stimulated depolarization current results. Consequently, the charge injection and transport in SRDs could be distinctly inhibited, realizing the enhancement of electrical properties. The results in this study could provide a facile and efficient strategy for achieving high-performance smart self-reporting dielectrics, which is appealing and vital for widespread applications of SRDs.

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“…However, the thorny problems, including high energy consumption during fabrication and recyclability after retirement, limit the sustainability of cable insulation. − Therefore, replacing thermosets with recyclable thermoplastics, such as polypropylene (PP) with superior insulating performance, has been proposed as an effective method to achieve the target. − Nevertheless, brittleness and low toughness make it difficult for PP to be directly used as a cable insulation. Although the problems can be solved by introducing elastomers, the sharp interface between the matrix and the rubber phase always leads to serious decline in the resistance against deformation and aging during its long-term operation at high temperatures. − …”

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confidence: 99%

Largely Improved Creep Resistance and Thermal-Aging Stability of Eco-Friendly Polypropylene High-Voltage Insulation by Long-Chain Branch-Induced Interfacial Constraints

Wu,

Sui,

Yang

et al. 2024

ACS Macro Lett.

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Polypropylene (PP)-based composites have attracted numerous attention as a replacement of prevailing cross-linked polyethylene (XLPE) for high-voltage insulation due to their ease of processing, recyclability, and excellent electrical performance. However, the poor resistances against high-temperature creep and thermal aging are obstacles to practical applications of PP-based thermoplastic high-voltage insulation. To address these problems, in this Letter, we synthesized an impact polypropylene copolymer (IPC) containing multifold long-chain branched (LCB) structures in phases, especially the interfaces between the PP matrix and the rubber phase. The results indicated that the structural stability of LCBIPC was significantly enhanced under extreme conditions. In comparison to IPC (without LCB structures), 24.1% less creep strain and 75.2% less unrecoverable deformation are achieved in LCBIPC at 90 °C. In addition, the thermal aging experiments were performed at 135 °C for 48 and 88 days for IPC and LCBIPC, respectively. The results show that the resistance against thermal aging was also enhanced in LCBIPC, which showed a 133% longer thermal aging life compared to IPC. Further results revealed that the interfacial layer between the PP matrix and the rubber phase was constructed in LCBIPC. The two phases are tightly linked by chemical bonds in LCB structures, leading to enforced constraints of the rubber phase at the micro level and better resistance performance against creep and thermal aging at the macro level. Evidently, the reported eco-friendly LCBIPC thermoplastic insulation shows great potential for applications in high-voltage cable insulation.

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All-organic lead-free thermochromic and dielectric switchable epoxy microcomposites from singly incorporating leuco dye microcapsules for advanced encryption

Cited by 10 publications

References 54 publications

Eco‐friendly polypropylene power cable insulation: Present status and perspective

Eco‐friendly polypropylene power cable insulation: Present status and perspective

Endowing smart self-reporting epoxy composites with superior electrical properties from ultralow-content electron-donating encapsulated microsensors

Largely Improved Creep Resistance and Thermal-Aging Stability of Eco-Friendly Polypropylene High-Voltage Insulation by Long-Chain Branch-Induced Interfacial Constraints

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