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    王友年

    • 教授     博士生导师   硕士生导师
    • 性别:男
    • 毕业院校:大连工学院
    • 学位:硕士
    • 所在单位:物理学院
    • 学科:等离子体物理
    • 办公地点:大连理工大学物理系楼306
    • 联系方式:0411-84707307
    • 电子邮箱:ynwang@dlut.edu.cn

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    Characterization of O-2/Ar inductively coupled plasma studied by using a Langmuir probe and global model

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    论文类型:期刊论文

    发表时间:2015-04-01

    发表刊物:PLASMA SOURCES SCIENCE & TECHNOLOGY

    收录刊物:SCIE、EI、Scopus

    卷号:24

    期号:2

    ISSN号:0963-0252

    关键字:O-2/Ar inductively coupled plasma; Langmuir probe; global model

    摘要:An O-2/Ar inductively coupled plasma is investigated by a Langmuir probe and a global model (volume averaged model). The electron density, electron temperature and electron energy distribution function (EEDF) are measured at different O-2 contents, gas pressures and applied powers. At fixed pressure and power, the electron density first drops quickly with the O-2 ratio and then tends to saturate in the high O-2 ratio range. The effective electron temperature exhibits completely opposite behaviors at low and high pressures. This is caused by the different evolving behaviors of low and high energy electrons of the EEDFs with the O-2 ratio. Both the Langmuir probe and the global model predict that the electron density of O-2/Ar mixed plasma first increases, peaks and then drops constantly, upon increasing the pressure. An analysis based on the simulation reveals that the non-monotonic variation of electron density with the pressure is due to the non-monotonic variation of the ionizations from both ground state O and metastable O*. Due to the strong ionizations, the electron density increases linearly with the power. The effective electron temperature is unchanged because the EEDF shape that determines the electron temperature is not varied upon increasing the power. The calculated electron density and temperature when varying the power agree better with the experiments at high pressure, i.e. 45 mTorr. The quantitative deviation between the model and the experiment when varying the pressure and the O-2 ratio can be explained by two aspects. (1) The electron energy probability function is assumed to have a Maxwellian distribution in the global model while the realistic EEDFs vary significantly with the pressure and/or the O-2 ratio, as revealed by the experiment. (2) The power transfer efficiency (i.e. the fraction of the power coupled into plasma) increases with the pressure.