Molecule self-assembly on alumina ceramic insulator to enhance its vacuum surface voltage withstand strength

Huo, Yankun; Liu, Wenyuan; Guo, Yufeng; Ke, Changfeng; Cheng, Jun; Chen, Changhua

doi:10.1063/5.0006233

Cited by 2 publications

(2 citation statements)

References 21 publications

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“…Extensive attempts have been made to improve vacuum surface insulation, for example, creating microstructures on the surface, − coatings that facilitate surface charge dissipation, − and materials with low secondary electron yield (SEY). − Surface microstructures (e.g., nonperiodic roughness, pores, and grooves) mitigate flashover by blocking the propagation of the SEEA. , Yet producing microstructures is generally not applicable for flexible films because the microstructure dimensions are usually comparable to or greater than the film thickness (∼ tens of μm). Coatings improving the surface conductivity can facilitate surface charge dissipation, especially in repetitive discharges.…”

Section: Introductionmentioning

confidence: 99%

Tailoring Organic/Inorganic Interface Trap States of Metal Oxide/Polyimide toward Improved Vacuum Surface Insulation

Yang,

Sun,

Guo

et al. 2023

ACS Appl. Mater. Interfaces

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High-voltage and high-power devices are indispensable in spacecraft for outer space explorations, whose operations require aerospace materials with adequate vacuum surface insulation performance. Despite persistent attempts to fabricate such materials, current efforts are restricted to trial-and-error methods and a universal design guideline is missing. The present work proposes to improve the vacuum surface insulation by tailoring the surface trap state density and energy level of the metal oxides with varied bandgaps, using coating on a polyimide (PI) substrate, aiming for a more systematical workflow for the insulation material design. First-principle calculations and trap diagnostics are employed to evaluate the material properties and reveal the interplay between trap states and the flashover threshold, supported by dedicated analyses of the flashover voltage, secondary electron emission (SEE) from insulators, and surface charging behaviors. Experimental results suggest that the coated PI (i.e., CuO@PI, SrO@PI, MgO@PI, and Al2O3@PI) can effectively increase the trap density and alter the trap energy levels. Elevated trap density is demonstrated to always yield lower SEE. In addition, increasing shallow trap density accelerates surface charge dissipation, which is favorable for improving surface insulation. CuO@PI exhibits the most remarkable increase in shallow trap density, and accordingly, the highest flashover voltage is 42.5% higher than that of pristine PI. This study reveals the critical role played by surface trap states in flashover mitigation and offers a novel strategy to optimize the surface insulation of materials.

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Section: Introductionmentioning

confidence: 99%

Tailoring Organic/Inorganic Interface Trap States of Metal Oxide/Polyimide toward Improved Vacuum Surface Insulation

Yang,

Sun,

Guo

et al. 2023

ACS Appl. Mater. Interfaces

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“…Therefore, solid insulation materials with high surface-insulating performances (high flashover threshold voltage) are pursued over the last half a century . The methods for improving surface-insulating performances include electric field optimization, , surface modification, − bulk modification, , and so forth . However, no effective solutions have still been found yet.…”

Section: Introductionmentioning

confidence: 99%

Two-Phase-Interfaced, Graded-Permittivity Titania Electrical Insulation by Atmospheric Pressure Plasmas

Kong

Zhao

Zhang

et al. 2021

ACS Appl. Mater. Interfaces

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Functionally graded materials (FGMs) exhibit unique properties and are expected to deliver outstanding and stable performance under extreme conditions. High-voltage, high-power FGM-based electric insulation commonly fails because of inadequate surface charge control (flashover) performance and stability of stacked layers of dielectric materials with graded permittivity εr. Here, we address these issues by interfacing the rutile and anatase TiO2 layers on a ceramic with very different εr values of 110, 48, and 9, respectively, using scalable, environment-benign, and energy-efficient atmospheric pressure plasma processing. The FGM drastically reduces the maximum electric field along the optimized surface by 66% and increases surface flashover voltage by 36 %, while featuring a remarkable (120/180 days) long-term stability. The mechanisms of the plasma-enabled graded layer formation are presented, which can be used for precise engineering of FGMs for diverse applications in other fields.

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Molecule self-assembly on alumina ceramic insulator to enhance its vacuum surface voltage withstand strength

Cited by 2 publications

References 21 publications

Tailoring Organic/Inorganic Interface Trap States of Metal Oxide/Polyimide toward Improved Vacuum Surface Insulation

Tailoring Organic/Inorganic Interface Trap States of Metal Oxide/Polyimide toward Improved Vacuum Surface Insulation

Two-Phase-Interfaced, Graded-Permittivity Titania Electrical Insulation by Atmospheric Pressure Plasmas

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