The characteristics of microplasma discharge propagation over the titanium surface covered with a thin oxide film

ADVANCES IN APPLIED PHYSICS Pub Date : 2021-12-22 DOI:10.51368/2307-4469-2021-9-6-449-463

V. Ivanov, M. Konyzhev, T. Kamolova, Anna Dorofeyuk

{"title":"The characteristics of microplasma discharge propagation over \nthe titanium surface covered with a thin oxide film","authors":"V. Ivanov, M. Konyzhev, T. Kamolova, Anna Dorofeyuk","doi":"10.51368/2307-4469-2021-9-6-449-463","DOIUrl":null,"url":null,"abstract":"The propagation and structure of a microplasma discharge initiated in vacuum by a pulsed plasma flow with a density of 1013 cm–3 on the surface of a titanium sample covered with a \nthin continuous dielectric titanium oxide film with a shickness of 2–6 nm were studied experimentally when the electric current of the discharge changes from 50 A to 400 A. \nIt was found that the microplasma discharge glow visually at the macroscale has a branched structure of the dendrite type, which at the microscale consists of a large number \nof brightly glowing “point” formations – cathode spots localized on the metal surface. The resulting erosion structure on the titanium surface is visually “identical” to the structure of \nthe discharge glow and consists of a large number of separate non-overlapping microcraters with characteristic sizes from 0.1–3 μm, which are formed at the sites of localization of \ncathode spots at distances of up to 20 μm from each other. It was found that the propagation of a single microplasma discharge over the titanium surface covered with a thin oxide film a \nthickness of 2–6 nm occurs at an average velocity of 15–70 m/s when the amplitude of the discharge electric current changes in the range of 50–400 A. In this case, the microplasma \ndischarge propagation on the microscale has a “jumping” character: the plasma of “motionless” burning cathode spots, during their lifetime 1 μs, initiates the excitation of new \nmicrodischarges, which create new cathode spots at localization distances of 1–20 μm from the primary cathode spots. This process repeated many times during a microplasma dis- \ncharge pulse with a duration from 0.1 ms to 20 ms.","PeriodicalId":228648,"journal":{"name":"ADVANCES IN APPLIED PHYSICS","volume":"6 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2021-12-22","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"ADVANCES IN APPLIED PHYSICS","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.51368/2307-4469-2021-9-6-449-463","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

The propagation and structure of a microplasma discharge initiated in vacuum by a pulsed plasma flow with a density of 1013 cm–3 on the surface of a titanium sample covered with a thin continuous dielectric titanium oxide film with a shickness of 2–6 nm were studied experimentally when the electric current of the discharge changes from 50 A to 400 A. It was found that the microplasma discharge glow visually at the macroscale has a branched structure of the dendrite type, which at the microscale consists of a large number of brightly glowing “point” formations – cathode spots localized on the metal surface. The resulting erosion structure on the titanium surface is visually “identical” to the structure of the discharge glow and consists of a large number of separate non-overlapping microcraters with characteristic sizes from 0.1–3 μm, which are formed at the sites of localization of cathode spots at distances of up to 20 μm from each other. It was found that the propagation of a single microplasma discharge over the titanium surface covered with a thin oxide film a thickness of 2–6 nm occurs at an average velocity of 15–70 m/s when the amplitude of the discharge electric current changes in the range of 50–400 A. In this case, the microplasma discharge propagation on the microscale has a “jumping” character: the plasma of “motionless” burning cathode spots, during their lifetime 1 μs, initiates the excitation of new microdischarges, which create new cathode spots at localization distances of 1–20 μm from the primary cathode spots. This process repeated many times during a microplasma dis- charge pulse with a duration from 0.1 ms to 20 ms.

查看原文本刊更多论文

微等离子体放电在氧化膜覆盖的钛表面上的传播特性

实验研究了密度为1013 cm-3的脉冲等离子体流在厚度为2 ~ 6 nm的连续介质氧化钛薄膜覆盖的钛样品表面上，当放电电流在50 ~ 400 a范围内变化时，微等离子体放电的传播和结构。研究发现，微等离子体放电辉光在宏观尺度上具有枝晶型的分支结构，在微观尺度上由大量发光的“点”结构组成，即金属表面的阴极斑点。钛表面的侵蚀结构在视觉上与放电辉光结构“相同”，由大量独立的、不重叠的微坑组成，特征尺寸在0.1-3 μm之间，这些微坑形成于阴极点定位的位置，彼此之间的距离可达20 μm。结果表明，当放电电流幅值在50 ~ 400 a范围内变化时，单次微等离子体放电在覆盖有2 ~ 6 nm氧化膜的钛表面上以15 ~ 70 m/s的平均速度传播。在这种情况下，微等离子体放电在微尺度上的传播具有“跳跃”特征:“静止”燃烧阴极点的等离子体在其寿命1 μs内激发新的微放电，在距离原阴极点1 ~ 20 μm的定位距离处产生新的阴极点。这个过程在微等离子体放电脉冲中重复多次，持续时间从0.1毫秒到20毫秒。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

ADVANCES IN APPLIED PHYSICS

自引率

0.00%

发文量