Characteristics of secondary electron emission and multipactor from a nested microtrap structure surface

Liu, Lu; Feng, Guobao; Chen, Bangdao; Wang, Ning; Cui, Wanzhao

doi:10.1063/5.0034979

Cited by 5 publications

(3 citation statements)

References 32 publications

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“…Current methods for suppressing secondary electron emission from surfaces include surface conformation and coating modifications [24][25][26]. The surface configuration approach usually achieves a reduction in secondary electron yield by constructing a surface trap structure and using the shielding effect of the microstructure to limit the emission of secondary electrons [27].…”

Section: Introductionmentioning

confidence: 99%

Gas Desorption and Secondary Electron Emission from Graphene Coated Copper Due to E-Beam Stimulation

Feng

Song

et al. 2023

Coatings

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The gas desorption and secondary electron multiplication induced by electron bombardment tend to induce severe low-pressure discharge effects in space microwave device cavities. Nevertheless, few studies have focused on both secondary electron emission and electron-stimulated gas desorption (ESD). Although the suppression of secondary electrons by graphene was found to be better in our previous study, it is still unclear whether the surface modification of graphene, which brings about different interfacial states, can also be manifested in terms of ESD. The deep mechanism of gas desorption and secondary electron emission from this extremely thin two-dimensional material under electron bombardment still needs further investigation. Therefore, this paper investigates the mechanism of graphene modification on Cu metal surface on the gas release and secondary electron emission properties under electron bombardment. The surface states of graphene-modified Cu were characterized, and the ESD yield and secondary electron yield of Cu/GoCu were investigated using a self-researched platform and analyzed using molecular dynamics simulations and electron Monte Carlo simulations. The results of the study showed that the most released component on the Cu surface under the bombardment of electrons was H2O molecules, while the most released component on the GoCu surface was H2 molecules. The graphene-modified samples showed a significant suppression effect on the secondary electron yield and ESD only in the low-energy region below 400 eV. This study can provide a valuable reference for suppressing low-pressure discharge and multipactor phenomena in space microwave components.

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Section: Introductionmentioning

confidence: 99%

Gas Desorption and Secondary Electron Emission from Graphene Coated Copper Due to E-Beam Stimulation

Feng

Song

et al. 2023

Coatings

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“…Since secondary electron emission properties are related to the nature and surface morphology of the material itself [14], researchers usually suppress secondary electron emissions by increasing the roughness of the material surface or by adding coatings with low SEY to the surface [15][16][17][18]. Graphene coatings have attracted the attention of the worldwide scientific community due to their fascinating properties and great potential for various applications [19][20][21][22], and are also highly inert in air [23,24].…”

Section: Introductionmentioning

confidence: 99%

Suppression of Secondary Electron Emissions on the Graphene-Coated Polyimide Materials Prepared by Chemical Vapor Deposition

Qi,

Ma,

Liu

et al. 2023

Coatings

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Polyimide thin-film materials are widely used in aerospace and particle gas pedals, etc., but the phenomenon of secondary electron emission occurred under vacuum conditions. The graphene-coated polyimide materials were prepared for this phenomenon to suppress secondary electron emissions. The graphene coating was prepared on the polyimide surface through chemical vapor deposition (CVD). Scanning electron microscope images (SEM), X-ray photoelectron spectrometer images (XPS), Raman spectroscopy, atomic force microscopy (AFM), and other analytical methods were used to characterize the properties of the prepared materials. The C1s XPS fine spectra and Raman curve analyses showed that the material has an abundant sp2 hybridized structure, and the sp2 structure can reduce secondary electron emissions. The C, O, and N contents in the tested samples were 65.85, 20.47, and 13.68 at.%, respectively. It was examined that the graphene coating had an inhibitory effect on the secondary electron emissions of polyimide materials, and the secondary electron emission yield (SEY) was significantly reduced. The results of secondary electron tests showed that the maximum SEY (δmax) of the polyimide material decreased from 1.72 to 1.52 after the preparation of the graphene coating. The mechanism of using a graphene coating to reduce the SEY of polyimide was analyzed from experimental and theoretical perspectives. The results of this study can provide research ideas for polyimide thin film materials in aerospace, particle gas pedals, and other applications.

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“…the effective reduction of secondary electron emission and multipactor suppression, has become a significant challenge. [12][13][14] Nowadays, more attention has been focused on the surface coating treatment with a thin film, like low-dimensional carbon-based materials. In other fields, the studying of the electronic transport characteristics of 2D system heterostructures is also a critical topic, particularly the future application of these 2D materials in manufacturing microelectronic devices.…”

Section: Introductionmentioning

confidence: 99%

Characteristics of secondary electron emission from few layer graphene on silicon (111) surface

Feng¹,

Li²,

Li³

et al. 2022

Chinese Phys. B

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As a typical 2D coating material, graphene has been utilized to effectively reduce secondary electron emission from the surface. Nevertheless, the microscopic mechanism and the dominant factor of secondary electron emission suppression remain controversial. Since traditional models rely on experimental bulk properties data which is scarcely appropriate for the 2D coating situation, this paper presents a first-principles based numerical calculation of the electron interaction and emission process for monolayer and multilayer graphene on the silicon (111) substrate. By using the anisotropic energy loss for the coating graphene, the electron transport process can be described more realistically. The real physical electron interactions, including the elastic scattering of electron-nucleus, inelastic scattering of the electron-extranuclear electron and electron-phonon effect, are considered and calculated based on the Monte Carlo method. To be independent of experimental data, the energy level transition theory based first-principles method and the full Penn Algorithm are used to calculate the energy loss function during the inelastic scattering. Variations of the energy loss function and interface electron density difference for 1L to 4L layer graphene coating GoSi are calculated, and their inner electron distributions and secondary electron emission are analyzed. Simulation results demonstrate that the dominant factor of the SEY inhibition for GoSi is the mechanism by inducing electrons deeper during the internal scattering process. In contrast, a low surface potential barrier due to the positive deviation of electron density difference in monolayer GoSi interface inversely weakens the suppression of graphene layer on secondary electron emission. Only when the graphene layer number is 3L, the contribution of surface work function to the secondary electron emission suppression presents to be slightly positive.

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Characteristics of secondary electron emission and multipactor from a nested microtrap structure surface

Cited by 5 publications

References 32 publications

Gas Desorption and Secondary Electron Emission from Graphene Coated Copper Due to E-Beam Stimulation

Gas Desorption and Secondary Electron Emission from Graphene Coated Copper Due to E-Beam Stimulation

Suppression of Secondary Electron Emissions on the Graphene-Coated Polyimide Materials Prepared by Chemical Vapor Deposition

Characteristics of secondary electron emission from few layer graphene on silicon (111) surface

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