The Effect of SiO 2 Particle Size on Crystallization Behavior and Space Charge Properties for SiO 2 /MMT/LDPE Composites

The matrix material used in this paper was low-density polyethene (LDPE), and the added particles selected were silicon oxide (SiO ) particles and montmorillonite (MMT) particles. The sizes of the SiO particles were 1 µm, 30 nm, and 100 nm, respectively; three kinds of SiO /MMT/LDPE multi-component...

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Veröffentlicht in:	Materials 2024-03, Vol.17 (7)
Hauptverfasser:	Jiang, Hongtao, Yuan, Hong, Yu, Qunguang, Xie, Jing
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description	The matrix material used in this paper was low-density polyethene (LDPE), and the added particles selected were silicon oxide (SiO ) particles and montmorillonite (MMT) particles. The sizes of the SiO particles were 1 µm, 30 nm, and 100 nm, respectively; three kinds of SiO /MMT/LDPE multi-component composites were prepared based on MMT/LDPE composites doped with MMT particles. The effect of the SiO particle size on the crystallization behavior and space charge properties of SiO /MMT/LDPE composites was studied. The crystalline behaviors and crystallinity of the materials were analyzed. At the same time, the changes in the relative dielectric constant ε and loss factor tanδ for each material with the influence of frequency were studied, and the space charge accumulation, residual characteristics, and apparent charge mobility of each material were explored. The results show that the smaller the size of the added particles, the smaller the grain size and the clearer the grain outline for the multi-composite material. After adding 30 nm SiO particles, the crystallinity of the material increases significantly. The microstructure formed by the addition of 100 nm SiO particles effectively restricts molecular chain movement and makes it difficult to establish the polarization of the composite. The incorporation of large-size particles can reduce the proportion of the crystalline structure for the material as a whole, resulting in the formation of a new structure to promote charge transfer. Among the three kinds of SiO particles, the addition of 30 nm SiO particles can effectively suppress the space charge, and the composite material has the lowest residual space charge after depolarization. The addition of 100 nm SiO particles can cause the accumulation of many homopolar charges near the anode.
doi_str_mv	10.3390/ma17071605
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The sizes of the SiO particles were 1 µm, 30 nm, and 100 nm, respectively; three kinds of SiO /MMT/LDPE multi-component composites were prepared based on MMT/LDPE composites doped with MMT particles. The effect of the SiO particle size on the crystallization behavior and space charge properties of SiO /MMT/LDPE composites was studied. The crystalline behaviors and crystallinity of the materials were analyzed. At the same time, the changes in the relative dielectric constant ε and loss factor tanδ for each material with the influence of frequency were studied, and the space charge accumulation, residual characteristics, and apparent charge mobility of each material were explored. The results show that the smaller the size of the added particles, the smaller the grain size and the clearer the grain outline for the multi-composite material. After adding 30 nm SiO particles, the crystallinity of the material increases significantly. The microstructure formed by the addition of 100 nm SiO particles effectively restricts molecular chain movement and makes it difficult to establish the polarization of the composite. The incorporation of large-size particles can reduce the proportion of the crystalline structure for the material as a whole, resulting in the formation of a new structure to promote charge transfer. Among the three kinds of SiO particles, the addition of 30 nm SiO particles can effectively suppress the space charge, and the composite material has the lowest residual space charge after depolarization. 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The microstructure formed by the addition of 100 nm SiO particles effectively restricts molecular chain movement and makes it difficult to establish the polarization of the composite. The incorporation of large-size particles can reduce the proportion of the crystalline structure for the material as a whole, resulting in the formation of a new structure to promote charge transfer. Among the three kinds of SiO particles, the addition of 30 nm SiO particles can effectively suppress the space charge, and the composite material has the lowest residual space charge after depolarization. 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title	The Effect of SiO 2 Particle Size on Crystallization Behavior and Space Charge Properties for SiO 2 /MMT/LDPE Composites
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