AI Article Synopsis
- The study investigates the effects of Polycarbonate (PC) and Polyvinylidene fluoride (PVDF) in creating asymmetric bilayer polymer dielectrics for electrostatic capacitors, focusing on their barrier characteristics and electrical properties based on the orientation of the applied electric fields.
- Findings indicate that while the dielectric constant of the composite remains constant regardless of the arrangement of PC and PVDF, the placement significantly affects the energy-storage capabilities.
- When PC is positioned at the negative electrode, it enhances the capacitor's performance by achieving a higher energy-storage density (5.48 J/cm) compared to other configurations and pure materials, thus demonstrating the potential of combining these polymers for better energy-storage solutions.*
Article Abstract
As a critical component of electrostatic capacitors, the polymer dielectric directly affects the performance of the capacitor. In this work, Polycarbonate (PC)/Polyvinylidene fluoride (PVDF) asymmetric bilayer polymer dielectrics were prepared, and the influence of different polymer materials' barrier characteristics on various electrical properties of composite dielectrics was studied by changing the direction of applied electric fields. Research has found that the dielectric constant of a composite dielectric is between PVDF and PC (approximately 4.8 at 10 Hz) and is independent of the relative position of PVDF and PC in the dielectric. However, the relative position of PC and PVDF has a significant impact on the energy-storage characteristics of composite dielectrics. When PVDF comes into contact with the negative electrode, even though PC has a higher hole barrier, the composite dielectric can only withstand a maximum electric-field strength of 400 MV/m, which is much lower than the maximum electric-field strength that pure PC can withstand (520 MV/m), and it only achieves an energy-storage density of 3.7 J/cm. When the PC comes into contact with the negative electrode, the high electron barrier of the PC effectively suppresses the injection of electrons at the electrode. It can withstand the same electric-field strength as PC (520 MV/m), achieving an energy-storage density of 5.48 J/cm, which is 1.46 times that of pure PC and 1.64 times that of PVDF. This experiment effectively combined the advantages of PC and PVDF by utilizing the electron/hole barrier of polymer materials to obtain a fully organic dielectric with excellent energy-storage performance.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11478430 | PMC |
| http://dx.doi.org/10.3390/polym16192750 | DOI Listing |
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