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| Natura: | Preprint |
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2024
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| Accesso online: | https://arxiv.org/abs/2410.01113 |
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| _version_ | 1866929523828719616 |
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| author | Khitun, Alexander |
| author_facet | Khitun, Alexander |
| contents | Graphene possesses a unique combination of physical properties including high carrier mobility and high current density it can sustain. In contrast to bulk metals, graphene does not completely screen the external electrostatic field. In this work, we consider the possibility of utilizing these properties for building devices for high-density electric energy storage. We consider a three-plate parallel plate capacitor where the middle plate is made of graphene and negatively charged. The electric forces of attraction acting on the electrons on the middle plate are compensated as the electric fields on both sides of the plate are not screened. However, it brings the system to an unstable equilibrium state. To make system stable, we consider fast oscillations similar to ones in Kapitza pendulum. AC electric current through the middle graphene plane creates a magnetic field. In turn, Lorentz force squeezes moving electrons towards the center of the middle plane. We present the results of numerical modeling showing the effect of AC electric current on electron movement. According to the estimates, the pseudopotential produced by the AC current may exceed 60 eV at room temperature. Such a large value of the pseudopotential is due to the high mobility and large current density in graphene. The electric field intensity between the edge plates and the middle plate may exceed the breakdown value for a conventional double-plate parallel-plate capacitors leading to the increase in the electric energy storage. The electric breakdown of the graphene capacitor is limited by the mechanical strength of the side plates. It may be possible to enhance the volume electric energy density above the gasoline 34 MJ/L. We also describe possible experiments to validate this idea. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2410_01113 |
| institution | arXiv |
| publishDate | 2024 |
| record_format | arxiv |
| spellingShingle | Three-plate graphene capacitor for high-density electric energy storage Khitun, Alexander Applied Physics Graphene possesses a unique combination of physical properties including high carrier mobility and high current density it can sustain. In contrast to bulk metals, graphene does not completely screen the external electrostatic field. In this work, we consider the possibility of utilizing these properties for building devices for high-density electric energy storage. We consider a three-plate parallel plate capacitor where the middle plate is made of graphene and negatively charged. The electric forces of attraction acting on the electrons on the middle plate are compensated as the electric fields on both sides of the plate are not screened. However, it brings the system to an unstable equilibrium state. To make system stable, we consider fast oscillations similar to ones in Kapitza pendulum. AC electric current through the middle graphene plane creates a magnetic field. In turn, Lorentz force squeezes moving electrons towards the center of the middle plane. We present the results of numerical modeling showing the effect of AC electric current on electron movement. According to the estimates, the pseudopotential produced by the AC current may exceed 60 eV at room temperature. Such a large value of the pseudopotential is due to the high mobility and large current density in graphene. The electric field intensity between the edge plates and the middle plate may exceed the breakdown value for a conventional double-plate parallel-plate capacitors leading to the increase in the electric energy storage. The electric breakdown of the graphene capacitor is limited by the mechanical strength of the side plates. It may be possible to enhance the volume electric energy density above the gasoline 34 MJ/L. We also describe possible experiments to validate this idea. |
| title | Three-plate graphene capacitor for high-density electric energy storage |
| topic | Applied Physics |
| url | https://arxiv.org/abs/2410.01113 |