2018
DOI: 10.1021/acs.macromol.8b00923
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High Dielectric Constant Sulfonyl-Containing Dipolar Glass Polymers with Enhanced Orientational Polarization

Abstract: Dipolar glass (DG) polymers, which utilize sub-T g orientational polarization (T g is the glass transition temperature) to enhance dielectric constants, are promising candidates for use in advanced electronic and power applications because conduction of space charges (electrons and impurity ions) is suppressed in the glassy state, and thus, the dielectric loss is low. In this study, we studied the effects of dipole density and dipole arrangement in sulfonyl-containing side-chain DG polymers on their dielectric… Show more

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Cited by 83 publications
(69 citation statements)
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“…First, a high‐performance polymer with reactive groups (CC), large dipole units (SO 2 , 4.5 D), and biphenyl structure (arylaryl), heat‐resistant poly(arylene ether sulfone)s (DPAES), was designed and synthesized as a matrix, which are attributed to limit molecular chains motion, enlarge dielectric constant, and thermal conductivity, respectively. [ 37,38 ] More notably, the crosslinking at the interface can reduce the defects at the interface, which can effectively inhibit the leakage current and reduce interfacial polarization, which is contributed to strengthen the electric breakdown strength and reduce energy loss. Moreover, the self‐crosslink of polymer can reduce dielectric relaxation originating from the movement of polymer chains segment at elevated temperatures and thus improve the mechanical properties and dielectric stability in a broad temperature range.…”
Section: Figurementioning
confidence: 99%
“…First, a high‐performance polymer with reactive groups (CC), large dipole units (SO 2 , 4.5 D), and biphenyl structure (arylaryl), heat‐resistant poly(arylene ether sulfone)s (DPAES), was designed and synthesized as a matrix, which are attributed to limit molecular chains motion, enlarge dielectric constant, and thermal conductivity, respectively. [ 37,38 ] More notably, the crosslinking at the interface can reduce the defects at the interface, which can effectively inhibit the leakage current and reduce interfacial polarization, which is contributed to strengthen the electric breakdown strength and reduce energy loss. Moreover, the self‐crosslink of polymer can reduce dielectric relaxation originating from the movement of polymer chains segment at elevated temperatures and thus improve the mechanical properties and dielectric stability in a broad temperature range.…”
Section: Figurementioning
confidence: 99%
“…Polarisation-electric-field relationship has also been commonly used as a method in various publications to determine the dielectric strength and energy density of a polymer film [19][20][21][22][23]. However, the test results are not reflecting the impact of surface roughness because of small active electrode areas in the tests.…”
Section: Introductionmentioning
confidence: 99%
“…In this work, a series of self-crosslinkable polymers with large dipole units (−SO 2 −, 4.5 D), [25,26] heat-resistant poly(arylene ether sulfone)s containing side propenyl groups (DPAES), are designed and synthesized as matrix, which are blended with BT nanoparticles to fabricate crosslinked polymer composites by thermal crosslinking for achieving enhanced dielectric properties at high temperatures. Herein, it is worth noting that these crosslinkable polymers do not produce by-products during the crosslinking process and the crosslinked network formed by self-crosslinking can play a confinement role on macromolecular chains motion at elevated temperatures.…”
mentioning
confidence: 99%