Your search keyword '"You-Nian, Wang"' showing total 611 results

1. Fast simulation strategy for capacitively-coupled plasmas based on fluid model.

Author

Jing-Ze Li, Ming-Liang Zhao, Yu-Ru Zhang, Fei Gao, and You-Nian Wang

Published

2025

2. Optimization of e+/e− pair yield during the interaction of a Doppler-boosted laser with a solid-density plasma

Author

De-Xuan Hui, Zhang-Hu Hu, Xian-Xiu Mei, and You-Nian Wang

Subjects

Physics, QC1-999

Abstract

The interaction of a Doppler-boosted laser with a solid-density plasma is investigated with two-dimensional particle-in-cell simulations, with special attention paid to the influences of laser incident angle on the yield of e+/e− pairs. With normal laser incidence, it is found that parts of plasma electrons are accelerated by the reflected laser and radiate high-energy γ-photons, which further make nearly head-on collisions with the subsequent incoming laser pulses. The nonlinear quantum parameters of the produced photons can reach 4.6, and the yield of e+/e− pairs increases by a factor of 4 compared to an incident angle of 45°. The optimization is easy to implement and can improve the signal-to-noise ratio in the experiments.

Published

2023

3. 3D modeling of a double-driver ion source considering ion magnetization: an investigation of plasma symmetry modulation methods

Author

Si-Yu Xing, Fei Gao, Yu-Ru Zhang, Miao Zhao, Guang-Jiu Lei, and You-Nian Wang

Subjects

three-dimensional fluid model, China Fusion Engineering Test Reactor (CFETR), double-driver ion source, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

A three-dimensional fluid model of a double-driver negative hydrogen ion source for China Fusion Engineering Test Reactor (CFETR) neutral beam injection is developed. In this model, the magnetic filter field is generated by 16 permanent magnets, which are surrounded by a soft iron. In order to accurately describe the transportation of charged species in the presence of strong magnetic field, both the electron magnetization and ion magnetization are taken into account, and the accuracy of the model has been proved by comparison with experimental data. By employing this model, the spatial distributions of the plasma parameters have been investigated, and three methods are proposed to optimize the symmetry at the bottom of the expansion region of a double-driver source. The results indicate that by adjusting the power of Driver I while keeping the power of Driver II constant, the symmetry of the electron density and negative hydrogen ion density could be improved. Furthermore, the inclusion of partition improves the symmetry of the electron temperature and density but has no impact on the regulation of the negative hydrogen ion density distribution. Finally, the application of magnetic shield can not only improve the symmetry of the electron density and negative hydrogen ion density, but also increase their densities at the bottom of the expansion region.

Published

2024

4. Effects of the excited states on electron kinetics and power absorption and dissipation in inductively coupled Ar plasmas

Author

Wei Yang, Fei Gao, and You-Nian Wang

Subjects

Physics, QC1-999

Abstract

The effects of the excited states on electron kinetics as well as plasma power absorption and dissipation are numerically studied in radio frequency low-pressure inductively coupled Ar plasmas. The model used in this work is based on the coupling of the kinetic module, the electromagnetic field module, and the global model module. The existence of excited states caused by the electron-impact excitations of the ground state of Ar decreases the electron temperature due to the significant depletion of the electron energy probability function in the inelastic energy range. The reduction in electron temperature decreases the power dissipation of an electron per unit volume and, therefore, increases the electron density for the fixed total power. The profile and maximum variations of the absorption power density indicate that the increased electron density suppresses the power deposition deeper into the plasma with inclusion of the electron-impact excitations of the ground state to excited states of Ar. However, the collision processes involving the excited states as reactants hardly affect the electron kinetics and electromagnetic field properties due to far lower densities of the excited states than that of the ground state of Ar.

Published

2022

5. Ion effects on the scaling of magnetic field amplification in plasmas with the system size

Author

Jie-Jie Lan, Zhang-Hu Hu, Xiao-Juan Wang, and You-Nian Wang

Subjects

current filamentation instability, magnetic field amplification, plasma ions effect, particle-in-cell simulation, Science, Physics, QC1-999

Abstract

Magnetic field amplification during the nonlinear stage of the current filamentation instability excited by ultra-relativistic electron beams is investigated with a two-dimensional electromagnetic particle-in-cell (PIC) simulation code, with special attention paid to the effects of plasma ions and the system size. The effect of plasma ions is shown to be significant and enhanced magnetic field amplification and beam energy deposition are found due to plasma cavity expansion and merger. When the system size in the transverse direction (perpendicular to the beam propagation direction) is enlarged by a factor of m , the transverse magnetic field energy is found to increase by a factor of m ^2 in the case of the plasma with movable ions, in contrast to m with immovable ions. The results are also confirmed by three-dimensional PIC simulations.

Published

2023

6. Secondary electron effect on sustaining capacitively coupled discharges: A hybrid modeling investigation of the ionization rate

Author

Ying-Ying Wen, Yu-Ru Zhang, Ge Jiang, Yuan-Hong Song, and You-Nian Wang

Subjects

Physics, QC1-999

Abstract

A one-dimensional fluid/Monte Carlo hybrid model was used to quantitatively study the secondary electron effect on sustaining the discharge by examining the ionization induced by bulk electrons and secondary electrons under different external discharge parameters. The results indicate that as the voltage increases, secondary electrons gain more energy from the stronger electric field. Therefore, the ionization region induced by secondary electrons expands and the ionization rate becomes comparable to and even exceeds that of bulk electrons. As the pressure increases, secondary electrons collide with neutrals sufficiently, thus their contribution to the plasma generation becomes pronounced and eventually they dominate the discharge. Besides, the distribution of the secondary electron ionization rate varies from flat to saddle-shape, due to the energy loss at the discharge center at higher pressures. Finally, when the discharge gap expands, the electron density calculated in the case without secondary electrons increases linearly, whereas the value first increases and then decreases in the model with secondary electrons taken into account. The results obtained in this work are important for improving the high aspect ratio etching process by secondary electrons.

Published

2019

7. Comparative measurement of plasma potential with tube probe and Langmuir probe

Author

Jian-quan Li, Wen-qi Lu, Jun Xu, Fei Gao, and You-nian Wang

Subjects

Physics, QC1-999

Abstract

Plasma potential measurements using the conventional Langmuir probe may cause an error due to the space charge effect. To solve the problem, a tube probe is proposed in this study which can minimize the space charge effect by collecting electrons with an orifice instead of the solid surface of the Langmuir probe. The I-V characteristic of the tube probe exhibits a clear turning point, accurately indicating the plasma potential. Comparing with the results of the conventional Langmuir probe, it suggests that the plasma potential measured by the Langmuir probe may be underestimated by about 0.1-0.2 Te/e, which may cause underestimation of the electron density by about 10%-20%. Combination use of the tube probe and the Langmuir probe is suggested for accurate measurement of the electron density.

Published

2018

8. Experimental Investigation of Nonlinear Standing Waves in DC/VHF Hybrid Capacitive Discharges

Author

You-Nian Wang, Quan-Zhi Zhang, Kai Zhao, Yu-Qing Guo, and Yong-Xin Liu

Subjects

Standing wave, Nuclear and High Energy Physics, Electron density, Materials science, Harmonics, Harmonic, Capacitively coupled plasma, Atomic physics, Condensed Matter Physics, Current density, Excitation, DC bias

Abstract

It is recognized that in very-high-frequency capacitively coupled plasma (VHF CCP) reactors, the standing wave effects can be enhanced by the presence of nonlinear higher harmonics self-excited by the plasma series resonance (PSR). In this work, we investigated the influence of the dc bias on the excitation of the nonlinear standing waves in a parallel-plate capacitively coupled dc/VHF (60 MHz) hybrid discharge sustained in argon, with both the dc source and the VHF source applied to the top electrode. A hairpin probe was employed to determine the axial/radial distribution of the electron density, while a high-frequency B-dot probe was used to measure the radial distributions of the harmonic magnetic field and the harmonic current density. With no dc bias applied, the nonlinear standing wave excitation was observed to be predominant; the high-order harmonic current density exhibited a main peak at the electrode center and one or more minor peaks between the electrode center and the edge, leading to a center-high electron density profile. With the addition of the dc source, the harmonic excitations and the corresponding nonlinear standing wave effect tend to be suppressed with the increase of dc bias, resulting in improved plasma uniformities. Underlying mechanisms of the suppression effect of the dc bias on the nonlinear standing wave excitation were analyzed.

Published

2021

9. Benchmarking and validation of a hybrid model for electropositive and electronegative capacitively coupled plasmas

Author

Yu-Ru Zhang, Jia-Wei Huang, Fang-Jie Zhou, Chang Lu, Jing-Yu Sun, Zi-Xuan Su, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

In this work, a fluid/Monte Carlo collision (fluid/MCC) hybrid model is developed based on the framework of multi-physics analysis of plasma sources. This hybrid model could be highly accurate in predicting the nonequilibrium phenomena in capacitively coupled plasmas and meanwhile avoid the limitation caused by the computational cost. Benchmarking against the well-established particle-in-cell/MCC (PIC/MCC) method and comparison with experimental data have been presented both in electropositive N2 discharges and electronegative O2 discharges. The results indicate that in N2 discharges, the ion density evolves from a uniform distribution to an edge-high profile as power increases. Besides, the electron energy distribution function (EEDF) at the bulk center exhibits a ‘hole’ at about 3 eV, and the ‘hole’ becomes less obvious at the radial edge, because more low energy electrons are generated there. In O2 discharges, the EEDF exhibits a Druyvesteyn-like distribution in the bulk region, and it evolves to a Maxwellian distribution in the sheath, indicating the dominant influence of the electric field heating there. The results obtained by the hybrid model agree well with those calculated by the PIC/MCC method, as well as those measured by double probe, except for a slight discrepancy in absolute values. The qualitative agreement achieved in this work validates the potential of this hybrid model as an effective tool in the deep understanding of plasma properties, as well as in the improvement of plasma processing.

Published

2023

10. High energy electrons induced by nonlinear effect in synchronized dual-level radio frequency pulsing capacitively coupled plasmas

Author

Fang-Fang Ma, Quan-Zhi Zhang, and You-Nian Wang

Subjects

Acoustics and Ultrasonics, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

The surface charging effect of positive ions at the trench bottom during the etching of dielectric materials has become a severe problem with the shrinkage of electronic feature dimensions. Pulsed plasmas have been widely used to overcome surface charging issues during plasma etching in industry. In this work, synchronized dual-level radio frequency pulsed modulation on capacitively coupled plasmas is investigated based on 1D3V particle-in-cell/Monte Carlo collision simulations. It is found that the plasma always remains a certain initial density during the dual-level pulse modulation, as the high frequency (HF) source still presents during pulse off time (with a reduced voltage amplitude), which may facilitate high processing efficiency. Meanwhile, many HF sheath oscillations are simulated at the initial stage of a pulse period, which induces vast high energy electrons to strike the electrode. When the HF voltage is maintained at a very low value during the pulse off (i.e. 0.1 V HF ), more electrons with higher energy bombard the bottom of the trench, effectively alleviating the charging effect. Furthermore, the nonlinear behavior of sheath oscillations is proved to be very sensitive to dual-frequency voltage amplitudes and pulse ramp-up times.

Published

2023

11. Investigation of stochastic heating and its influence on plasma radial uniformity in biased inductively coupled Ar discharges by hybrid simulation

Author

Jia-Wei Huang, Ming-Liang Zhao, Yu-Ru Zhang, Fei Gao, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

A bias power is usually applied in inductively coupled plasmas (ICP) to realize the separate control of the plasma density and the ion energy. In this research, a two-dimensional fluid/electron Monte Carlo hybrid model is developed to self-consistently investigate the bias effect on the stochastic heating and on the radial homogeneity in a biased argon ICP operated at low pressure (3 mTorr). The results show that the temporal evolution of the stochastic heating exhibits a plateau and a peak when the sheath collapses at high bias voltages, due to the limited sheath heating and the electron inertia. In addition, the plasma density in the diffusion chamber increases with bias voltage and bias frequency, because of the more pronounced stochastic heating both at the substrate and at the grounded wall. In the main discharge chamber, the plasma density decreases with bias voltage, due to the compression of the bulk plasma region, and this trend becomes less obvious at high bias frequency, because of the enhanced power absorption caused by the stochastic heating. Therefore, it is concluded that by tuning the bias voltage and bias frequency, the plasma radial uniformity could be modulated efficiently, which is very important for improving plasma processing.

Published

2023

12. A comprehensive study on the electron cyclotron resonance effect in a weakly magnetized capacitively coupled RF plasma: experiment, simulation and modeling

Author

Jia-Rui Liu, Yong-Xin Liu, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

The electron cyclotron resonance (ECR) effect in a weakly magnetized capacitively coupled radio frequency (RF) plasma was previously observed with optical emission spectroscopy (OES) in experiments and analyzed by particle-in-cell/Monte Carlo collision (PIC/MCC) simulations (Zhang et al 2022 Plasma Sources Sci. Technol. 31 07LT01). When the electron cyclotron frequency equals the RF driving frequency, the electron can gyrate in phase with the RF electric field inside the plasma bulk, being continuously accelerated like microwave ECR, leading to prominent increases in the electron temperature and the excitation or ionization rate in the bulk region. Here, we study further the basic features of the RF ECR and the effects of the driving frequency and the gas pressure on the RF ECR effect by OES and via PIC/MCC simulations. Additionally, a single electron model is employed to aid in understanding the ECR effect. It is found that the maximum of the measured plasma emission intensity caused by ECR is suppressed by either decreasing the driving frequency from 60 MHz to 13.56 MHz or increasing the gas pressure from 0.5 Pa to 5 Pa, which shows a qualitative agreement with the change of the excitation rate obtained in the simulations. Besides, the simulation results show that by decreasing the driving frequency the electron energy probability function (EEPF) changes from a convex to a concave shape, accompanied by a decreased electron temperature in the bulk region. By increasing the gas pressure, the EEPF and the electron temperature show a reduced dependence on the magnitude of the magnetic field. These results suggest that the ECR effect is more pronounced at a higher frequency and a lower gas pressure, primarily due to a stronger bulk electric field, together wih a shorter gyration radius and lower frequency of electron–neutral collisions.

Published

2023

13. Parallelization and optimization of electrostatic Particle-in-Cell/Monte-Carlo Coupled codes as applied to RF discharges.

Author

Hongyu Wang 0001, Wei Jiang, and You-Nian Wang

Published

2009

14. Permeability enhancement of the KcsA channel under radiation of a terahertz wave

Author

Zhang-Hu Hu, Wen-Ping Lv, De-Xuan Hui, Xiao-Juan Wang, and You-Nian Wang

Abstract

Potassium ion channels are essential elements in cellular electrical excitability and help maintain a resting potential in nonexcitable cells. Their universality is based on a unique combination of strong selectivity for K^{+} ions and near-diffusion-limited permeation efficiency. Understanding how the channel regulates the ion conduction would be instructive to the treatment of ion channelopathies. In this work, by means of molecular dynamics simulations, we demonstrate the significantly enhanced permeation of KcsA channel in reaction to an external terahertz wave, due to the effective response of the K^{+} ions in the selectivity filter regions of the channel. Compared to the case without external terahertz wave, a fourfold increase in the ion current through the channel is found.

Published

2022

15. Experimental investigation of the radially-dependent ignition process in a pulsed capacitively coupled RF discharge: Effects of pressure, voltage and afterglow duration

Author

Zi-Xuan Su, Kai Zhao, Ke Jiang, Yong-Xin Liu, Fei Gao, and You-Nian Wang

Subjects

Condensed Matter Physics, Mathematical Physics, Atomic and Molecular Physics, and Optics

Abstract

The effects of the gas pressure, the voltage amplitude and the afterglow duration on the ignition process over 300 mm-diameter in a pulse-modulated capacitively coupled radio-frequency argon discharge are experimentally investigated. A home-made optical probe is used to measure the optical emission intensity (OEI) as a function of time since the beginning of each pulse at various radial positions. A voltage and a current probe are used to measure the voltage and current waveforms at the power feeding point and then the time-dependent power deposition is also obtained. It was found that the radial profile of the OEI exhibits complex evolution when changing these external conditions. At lower pressures, the ignition occurs earlier, and the radial-integral OEI and the power deposition overshoot more slightly during the ignition. By increasing the pressure, these two quantities overshoot more significantly, and the OEI gradually evolves from an edge-peaked radial profile to a center-high radial profile for a given time when the OEI increases rapidly during the ignition. When increasing the voltage amplitude, the ignition tends to occur earlier, featuring a more significant overshoot of the OEI and power deposition at a higher voltage. Compared to that at high voltage, the OEI exhibits a significant center-high radial profile at low voltage amplitude during the ignition. By increasing the afterglow duration, T off, the ignition is delayed and the overshoot becomes more significant, due to a lower initial electron density when each pulse is turned on. During the phase when the growth rate of the OEI versus time is maximum, the OEI exhibits different radial distributions, i.e., it appears a center-high profile at short T off, an edge-peaked profile at intermediate T off, and a center-high profile at relatively long T off.

Published

2023

16. Optimization of overshoot in the pulsed radio frequency inductively coupled argon plasma by step waveform modulation

Author

Xiang-Yun Lv, Quan-Zhi Zhang, Ke Jiang, Fei Gao, and You-Nian Wang

Subjects

General Physics and Astronomy

Abstract

The pulsed inductively coupled plasma (ICP) has considerable potential to satisfy multiple stringent scaling requirements for use in the semiconductor industry. However, overshoot of plasma parameters during the rising period of the pulse affects the stability and uniformity of the plasma and can lead to a breakdown of the wafer and over-sputtering of the film. In this study, a step waveform modulation method is used to reduce the overshoot at the initial stage of the pulse. The behavior of the discharge is monitored by measuring (i) the modulated step waveform signal on the function generator, (ii) the input power (by a time-resolved VI-probe), and (iii) the amplitudes of the coil voltage and current (by voltage and current probes, respectively), as well as (iv) the plasma parameters including the electron density, the effective electron temperature, and the electron energy probability distribution function (by a time-resolved Langmuir probe). It was found that the state of the plasma can be controlled by changing the waveform, such as varying the time of the rising edge, varying the initial amplitude, and varying the duration of the low-high amplitude. The results indicated that the overshoot value of the electron density can be reduced by using a low-high step waveform. When the amplitude of the waveform was 500/550 mV and the duration was 200/300 μs, the overshoot value observed was 1/4 of that of the conventional ICP pulse discharge. In addition, increasing the duty cycle of the pulse could also reduce the overshoot value due to the high electron density that occurs during the afterglow period. Moreover, the plasma can reach a steady state more quickly at high pressure by using a step waveform of high amplitude.

Published

2023

17. Interactions of the external charged particle beams with double-layer two-dimensional electron gases separated by insulating medium

Author

Chun-Zhi Li, Zoran L. Mišković, You-Nian Wang, Su-Ri Na, and Yang-Yang Jian

Subjects

Double layer (biology), Nuclear and High Energy Physics, Radiation, Materials science, 02 engineering and technology, Electron, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Molecular physics, Charged particle, 0103 physical sciences, Image force, Stopping power (particle radiation), General Materials Science, 010306 general physics, 0210 nano-technology, Fermi gas, Plasmon

Abstract

The interactions of a fast-moving charged particle with two parallel layers, each containing a two-dimensional electron gas (2DEG), which are separated by an insulating material, are investigated b...

Published

2019

18. Effects of high-intensity pulsed ion beam irradiation on the structural thermal stability of Fe80Si7.43B12.57 metallic glass

Author

Qi Zhang, Xianxiu Mei, Xiaonan Zhang, You-Nian Wang, Gennady E. Remnev, S. K. Pavlov, and Tong Guan

Subjects

Amorphous metal, Ion beam, Mechanical Engineering, High intensity, Condensed Matter::Disordered Systems and Neural Networks, 01 natural sciences, Molecular physics, 010305 fluids & plasmas, Amorphous solid, Ion beam irradiation, Nuclear Energy and Engineering, Transmission electron microscopy, 0103 physical sciences, General Materials Science, Thermal stability, Irradiation, 010306 general physics, Civil and Structural Engineering

Abstract

A high-intensity pulsed ion beam was used to irradiate Fe80Si7.43B12.57 metallic glass at different energy densities and numbers of pulses to study its structural thermal stability. A large number of round holes and a few bumps appeared on the surface of the glass after 300 pulses. No obvious damage was observed on the surface after irradiation at different energy densities. High-resolution transmission electron microscopy showed that this irradiation had a strong influence on the near-surface atomic arrangement of the glass. Irradiation induced strong migration and aggregation of atoms within the glass, causing an uneven atomic arrangement. Although there was an ordered arrangement of atoms, the metallic glass remained amorphous. The surface reflectivity of the metallic glass decreased slightly after irradiation. The number of irradiation pulses had greater impact on this Fe-based metallic glass than their energy density.

Published

2019

19. Electron heating mode transition induced by the magnetic confinement of secondary electrons in capacitively coupled radio frequency discharges

Author

Jing-Yu Sun, Hui Wen, Quan-Zhi Zhang, Julian Schulze, Yong-Xin Liu, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

Based on particle-in-cell and test-particle simulations, an α- to γ-mode transition of the electron power absorption dynamics is found to be induced as a function of an externally applied transverse magnetic field in low pressure capacitively coupled radio frequency discharges operated in argon. This transition is caused by the increased magnetic confinement of energetic ion-induced secondary electrons (γ-electrons) at higher magnetic fields. If a transverse magnetic field is applied, γ-electrons, that are accelerated to high energies by the sheath electric field, are confined in the vicinity of the sheath. Due to their gyromotions they are returned periodically to the adjacent sheath and interact repetitively with the sheath electric field. Such confined γ-electrons are, thus, effectively multiplied by ionization collisions in the vicinity of the sheath, thereby resulting in a significant enhancement of the local ionization rate and the plasma density. In such cases, the energy coupling efficiency of γ-electrons is greatly enhanced, implying that the discharge operates in a magnetized γ-mode. Moreover, the effects of the magnetic field on ion properties and ionization dynamics at different driving frequencies and operating pressures are studied.

Published

2022

20. Measurement of neutral gas temperature in inductively coupled Ar and Ar/O2 plasmas

Author

Peng-Cheng Du, Fang-Jie Zhou, Kai Zhao, Yong-Xin Liu, Fei Gao, and You-Nian Wang

Subjects

General Physics and Astronomy

Abstract

In low-temperature inductively coupled radio frequency (rf) plasmas, electrons and ions that gain energy from the electric field can transfer a portion of energy to neutral particles. The resulting radial variation of the neutral gas temperature [Formula: see text] can significantly influence the radial distributions of reaction rates and radical densities on the substrate, thus affecting the etching/film deposition uniformity. In this work, we perform an experimental study on the dependence of the neutral gas temperature [Formula: see text] on external parameters (i.e., rf power, pressure, and gas component) in inductively coupled Ar and Ar/O2 plasmas by using a fiber Bragg grating sensor. To analyze the correlation between [Formula: see text] and the plasma characteristics, a Langmuir probe is used to measure the electron density [Formula: see text], effective electron temperature [Formula: see text], and ion density [Formula: see text] under the same discharge conditions. It is found that in both Ar and Ar/O2 plasmas, neutral gas heating is sensitive to plasma density. As the plasma density increases with the pressure/power, the collisions of ions and electrons with neutral particles are enhanced so that [Formula: see text] increases monotonically. With the increase of O2 content, [Formula: see text] and [Formula: see text] are observed to decrease due to enhanced dissociation and excitation of O2, leading to a decrease in [Formula: see text]. The radial profile of [Formula: see text] exhibits a parabolic distribution in pure Ar discharges, whereas it evolves through a center-flat shape into a saddle shape with the increase of O2 content. The variation of [Formula: see text] with rf power during the E-to-H mode transition is also presented and discussed.

Published

2022

21. Fundamental study towards a better understanding of low pressure radio-frequency plasmas for industrial applications

Author

Yong-Xin Liu, Quan-Zhi Zhang, Kai Zhao, Yu-Ru Zhang, Fei Gao, Yuan-Hong Song, and You-Nian Wang

Subjects

General Physics and Astronomy

Abstract

Two classic radio-frequency (RF) plasmas, i.e., the capacitively and the inductively coupled plasmas (CCP and ICP), are widely employed in material processing, e.g., etching and thin film deposition, etc. Since RF plasmas are usually operated in particular circumstances, e.g., low pressures (mTorr–Torr), high-frequency electric field (13.56 MHz–200 MHz), reactive feedstock gases, diverse reactor configurations, etc., a variety of physical phenomena, e.g., electron resonance heating, discharge mode transitions, striated structures, standing wave effects, etc., arise. These physical effects could significantly influence plasma-based material processing. Therefore, understanding the fundamental processes of RF plasma is not only of fundamental interest, but also of practical significance for the improvement of the performance of the plasma sources. In this article, we review the major progresses that have been achieved in the fundamental study on the RF plasmas, and the topics include 1) electron heating mechanism, 2) plasma operation mode, 3) pulse modulated plasma, and 4) electromagnetic effects. These topics cover the typical issues in RF plasma field, ranging from fundamental to application.

Published

2022

22. Enhanced heating in plasma bulk due to electron cyclotron resonance in weakly magnetized capacitively coupled plasmas

Author

Quan-Zhi Zhang, Jia-Rui Liu, Yong-Xin Liu, Wen-Qi Lu, Jing-Yu Sun, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

An enhanced electron heating mechanism based on a resonance between the cyclotron motion of electrons and radio frequency (rf) electric field in the plasma bulk is reported in weakly magnetized capacitively coupled argon plasmas at low pressure. When the electron cyclotron frequency coincides with the applied power source frequency, the bulk electrons can continuously acquire energy from the background electric field within certain rf periods during the cyclotron motion, inducing overall distinct increase of excitation rate and electron temperature in the plasma bulk. This enhanced electron heating effect has been examined by a combination of kinetic particle simulations, experimental measurements, and an analytical model, and the dynamics of electrons are revealed at resonant conditions.

Published

2022

23. Collective energy-spectrum broadening of a proton beam in a gas-discharge plasma

Author

Rui Cheng, Fei Gao, De-Xuan Hui, Yanhong Chen, Zhao Wang, Bing-Li Zhu, Zhang-Hu Hu, Zexian Zhou, Yongtao Zhao, Yu Lei, Yang Yang, You-Nian Wang, Jie Yang, and Yuyu Wang

Subjects

Physics, Proton, Physics::Plasma Physics, Physics::Accelerator Physics, Plasma, Fusion power, Atomic physics, Ion trapping, Instability, Beam (structure), Excitation, Electric discharge in gases

Abstract

An accurate understanding of ion-beam transport in plasmas is crucial for applications in inertial fusion energy and high-energy-density physics. We present an experimental measurement on the energy spectrum of a proton beam at 270 keV propagating through a gas-discharge hydrogen plasma. We observe the energies of the beam protons changing as a function of the plasma density and spectrum broadening due to a collective beam-plasma interaction. Supported by linear theory and three-dimensional particle-in-cell simulations, we attribute this energy modulation to a two-stream instability excitation and further saturation by beam ion trapping in the wave. The widths of the energy spectrum from both experiment and simulation agree with the theory.

Published

2021

24. Fluid simulation of the superimposed dual-frequency source effect in inductively coupled discharges

Author

Xiao-Yan Sun, Yu-Ru Zhang, You-Nian Wang, and Jian-Xin He

Subjects

Physics, Argon, chemistry.chemical_element, Plasma, Current source, Low frequency, Condensed Matter Physics, chemistry, Electric field, Atomic physics, Inductively coupled plasma, Diffusion (business), Current (fluid)

Abstract

Superimposition of dual frequencies (DFs) is one of the methods used for controlling plasma distribution in an inductively coupled plasma (ICP) source. The effects of a superimposed DF on the argon plasma characteristics have been investigated using a two-dimensional self-consistent fluid model. When both currents are fixed at 6 A, the plasma density drops with decrease in one of the source frequencies due to less efficient heating and the plasma uniformity improves significantly. Moreover, for ICP operated with superimposed DFs (i.e., 4.52 MHz/13.56 MHz and 2.26 MHz/13.56 MHz), the current source exhibits the same period as the low frequency (LF) component, and the plasma density is higher than that obtained at a single frequency (i.e., 4.52 and 2.26 MHz) with the same total current of 12 A. However, at superimposed current frequencies of 6.78 MHz/13.56 MHz, the plasma density is lower than that obtained at a single frequency of 6.78 MHz due to the weaker negative azimuthal electric field between two positive maxima during one period of 6.78 MHz. When the superimposed DF ICP operates at 2.26 and 13.56 MHz, the rapid oscillations of the induced electric field become weaker during one period of 2.26 MHz as the current ratio of 2.26 MHz/13.56 MHz rises from 24 A/7 A to 30 A/1 A, and the plasma density drops with the current ratio due to weakened electron heating. The uniformity of plasma increases due to sufficient diffusion under the low-density condition.

Published

2021

25. Effects of chamber size on electron bounce-resonance heating and power deposition profile in a finite inductive discharge

Author

Wei Yang, Fei Gao, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

Effects of chamber size on electron bounce-resonance heating (BRH) and power deposition profile are numerically studied in a finite inductive Ar discharge under a low-pressure range of 0.3–3 Pa. The BRH characterized by a plateau formation in the electron energy probability function (EEPF) exists only at the small chamber radius and relatively low pressure and is enhanced at a larger chamber height. It is attributed to a remarkable increase in the energy diffusion coefficient caused by electron heating at the first bounce resonance condition. As increasing chamber radius and pressure, the enhancement in the energy diffusion coefficient caused by electron–electron collisions tends to Maxwellianize the EEPF, thus resulting in weakness and even disappearance of the BRH. For relatively low pressure, the number of positive and negative power deposition regions increases with increasing chamber radius, and there is no region of negative power deposition at the small chamber radius where the skin depth becomes closer to the chamber radius.

Published

2022

26. Striations in dual-low-frequency (2/10 MHz) driven capacitively coupled CF4 plasmas

Author

Xiao-Kun Wang, Xiang-Yu Wang, Yong-Xin Liu, Julian Schulze, Zoltán Donkó, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

In electronegative radiofrequency plasmas, striations (STRs) can appear if the bulk plasma is dominated by positive and negative ions that can react to the driving frequency. Here, we investigate such self-organized structures in dual-frequency (2/10 MHz) capacitively coupled CF4 plasmas by phase-resolved optical emission spectroscopy and particle-in-cell/Monte Carlo collision simulations. This choice of the frequencies is made to ensure that the ions can react to both the lower (2 MHz, ‘low frequency’, LF) and the higher (10 MHz, ‘high frequency’, HF) components of the excitation waveform. A strong interplay of the two excitation components is revealed. As the STRs appear in the plasma bulk, their number depends on the length of this region. By increasing the LF voltage, ϕ LF, the sheath widths at both electrodes increase, the bulk is compressed and the number of STRs decreases. The maximum ion density decreases slightly as a function of ϕ LF, too, due to the compressed plasma bulk, while the minimum of the ion density remains almost constant. The spatio-temporal distributions of the excitation and ionization rates are modulated both by the LF and HF with maxima that occur at the first HF period that follows the complete sheath collapse at a given electrode. These maxima are caused by a high local ambipolar electric field. At a given phase within a HF period the current density is different at different phases within the LF period because of frequency coupling. The LF components of the F− ion velocity and of the electric field are much lower than the respective HF components due to the lower LF component of the displacement current in the sheaths. The LF component of the total current is dominated by the ion current at low values of ϕ LF but by the electron current at high values. The HF component of the total current is dominated by the electron current and decreases slightly as a function of ϕ LF.

Published

2022

27. Simulation study of coupled two-stream and current filamentation instability excited by accelerator electron beams in plasmas

Author

Han-Lin Li, Zhang-Hu Hu, Quan-Tang Zhao, Rui Cheng, Yong-Tao Zhao, Zi-Min Zhang, Xue-Chun Li, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

A gas-discharge plasma device is simulated with COMSOL software, and the obtained plasma density profile is input into a two-dimensional particle-in-cell code, in which the transport of relativistic electron beams in the plasma with an actual density profile is investigated. The results show that the device can produce a wide range of high-density plasmas with the maximum density approaching [Formula: see text] m−3. With the relativistic electron beams produced from a linear electron accelerator, the gas-discharge plasma is shown to be an ideal medium for the investigation of coupled two-stream and current filamentation instability.

Published

2022

28. Experimental study on the ignition process of a pulsed capacitively coupled RF discharge: Effects of gas pressure and voltage amplitude

Author

Xiang-Yu Wang, Xiao-Kun Wang, Kai Zhao, Yong-Xin Liu, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

The effects of gas pressure and voltage amplitude on the ignition process of a pulse capacitively coupled RF argon discharge are experimentally investigated. The electron density is measured by a hairpin probe, the spatiotemporal distribution of the electron impact excitation dynamics is determined by phase resolved optical emission spectroscopy, and the electrical parameters are obtained by analyzing the measured current and voltage waveforms. In this work, the pulse plasma is ignited with few initial electrons, so the ignition process behaves like gas breakdown. Based on the measured RF breakdown curve, the gas pressures and voltage amplitudes are selected, and then different characteristics of ignition processes are compared and discussed in detail. Particularly, the spatiotemporal pattern of the electron impact excitation rate obtained within the selected pressure range, as well as other results, aid the intuitive understanding of a typical “V-shaped” RF breakdown curve. At lower pressures, the excitation pattern exhibit shorter and tilted regions, ending at electrodes during the early ignition stage, implying a substantial electron energy loss, while at relatively high pressures, the excitation pattern becomes wider and less tilted, and the proportion of electron energy consumed by excitation processes increases. In addition, by increasing the voltage amplitude, the ignition is advanced and becomes more significant, manifesting a faster increase in discharge current and a stronger overshoot of RF power deposition. Meanwhile, at high voltage amplitude, the excitation pattern exhibits complex spatiotemporal distribution due to enhanced local electric field when the plasma emission intensity overshoots.

Published

2022

29. Power transfer efficiency and the power threshold for E–H mode transition in inductively coupled plasmas

Author

Peng-Cheng Du, Ming-Liang Zhao, Hong Li, Fei Gao, and You-Nian Wang

Subjects

General Physics and Astronomy

Abstract

The effects of gas pressure and gas component on the power transfer efficiency [Formula: see text] and transition power threshold [Formula: see text] during the E–H mode transition in inductively coupled plasmas are studied. The evolutions of [Formula: see text] during the E–H mode transition in pure Ar and Ar/O2 discharges are similar, i.e., in E-mode discharge, [Formula: see text] slightly increases with raising the applied power ([Formula: see text] is below 30%), whereas, an abruptly upward jump of nearly two to four times for [Formula: see text] occurs when the discharge transits to H-mode, and then [Formula: see text] monotonously increases with increasing the applied power. In addition, as the pressure rises, [Formula: see text] increases rapidly first and then slowly in pure Ar discharge. However, [Formula: see text] in Ar/O2 mixture gases discharge shows a non-monotonic behavior. It reveals a tendency of first increase at low pressures and then decreases at high pressures, which is because the resistive component of the plasma varies with the electron density [Formula: see text] and the electron effective collision frequency [Formula: see text]. Furthermore, a non-monotonic behavior of transition power threshold [Formula: see text] with the pressure is found, i.e., with increasing the pressure, [Formula: see text] first decreases and then increases. It may be caused by the threshold electron density, which is constant at low pressures [Formula: see text] but increases at high pressures [Formula: see text].

Published

2022

30. Experimental investigation of the electron sheath resonance (ESR) effect in parallel plate radio-frequency capacitively coupled plasmas

Author

Ling-ling Ding, Wen-qi Lu, Quan-zhi Zhang, Jun Xu, Zhen-feng Ding, and You-nian Wang

Subjects

Condensed Matter Physics

Abstract

We have conducted a systematic experimental investigation on the electron heating mechanism named as electron sheath resonance (ESR) effect, with a parallel plate discharge configuration under various experimental conditions. In all conditions, a clear plasma density peak was observed at the magnetic field for ESR, providing a direct evidence for the effect. Further analysis suggests that the more significant ESR effect should appear at higher frequency, lower pressure discharges with larger electrodes. The results form a basis for further studies of the ESR effect, which is also meaningful to practical applications such as etching and thin film deposition processes.

Published

2022

31. Collisionless magnetized sheath resonance heating induced by a transverse magnetic field in low-pressure capacitive rf discharges

Author

Jing-Yu Sun, Quan-Zhi Zhang, Julian Schulze, and You-Nian Wang

Subjects

Physics::Plasma Physics, Condensed Matter Physics

Abstract

The mechanism of resonance heating between the gyrating electrons and the oscillating sheath induced by a small transverse magnetic field in low-pressure capacitively coupled plasmas is investigated. The gyrating electrons will coherently collide with the expanding sheath if the electron gyro-frequency coincides with half the driving frequency. These electrons will gain substantial energy from collision-less heating, which strongly enhances the electron power absorption and the plasma density at a constant driving voltage. The electron kinetics is revealed at resonant conditions by particle simulations. Our numerical results demonstrate that the relation between the magnetic field and the driving frequency determines this resonance effect. Besides, it is found that the operating pressure, electrode gap, and driving voltage all strongly affect this electron resonance mechanism. The resonance effect is more pronounced at the conditions of low pressure, large gap, and high voltage.

Published

2022

32. Non-Linear Sheath Oscillation Mechanism in Symmetric Capacitively Coupled Plasma Sheaths

Author

Quan-Zhi Zhang, Jing-Yu Sun, Yuan-Hong Song, and You-Nian Wang

Published

2020

33. Resonant sheath heating in weakly magnetized capacitively coupled plasmas due to electron-cyclotron motion

Author

Jing-Yu Sun, You-Nian Wang, Julian Schulze, Wen-Qi Lu, Yu-Qing Guo, and Quan-Zhi Zhang

Subjects

Physics, Period (periodic table), Cyclotron, Kinetics, Resonance, Electron, Plasma, equipment and supplies, law.invention, Magnetic field, Physics::Plasma Physics, law, Physics::Space Physics, Radio frequency, Atomic physics

Abstract

An electron heating mechanism based on a resonance between the cyclotron motion of electrons and the radio frequency sheath oscillations is reported in weakly magnetized capacitively coupled plasmas at low pressure. If half of the electron cyclotron period coincides with the radio frequency period, then electrons will coherently collide with the expanding sheath and gain substantial energy, which enhances the plasma density. A relation between the magnetic field and the driving frequency is found to characterize this resonance effect and the kinetics of electrons are revealed at resonance conditions for various driving frequencies.

Published

2020

34. Realistic treatment for secondary electron emission in hybrid DC/DF capacitively coupled discharge

Author

You-Nian Wang, Jing-Yu Sun, Yong-Xin Liu, and Quan-Zhi Zhang

Subjects

Argon, Materials science, chemistry, Secondary emission, Ionization, Monte Carlo method, Direct current, chemistry.chemical_element, Electric current, Atomic physics, Condensed Matter Physics, Electromagnetic radiation, Charged particle

Published

2020

35. Electron power absorption mode transition in capacitively coupled Ar/CF4 discharges: hybrid modeling investigation

Author

Ying-Ying Wen, Xin-Yang Li, Yu-Ru Zhang, Yuan-Hong Song, and You-Nian Wang

Subjects

Acoustics and Ultrasonics, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

In this work, the electron power absorption mode transition in capacitively coupled Ar/CF4 discharges is investigated by using a one-dimensional fluid/electron Monte Carlo hybrid model. Different electron power absorption modes are observed under various external discharge conditions, which could be explained by examining the contribution of bulk electrons and secondary electrons respectively. The results indicate that as the gap increases, the electron power absorption mode changes from the drift-ambipolar (DA) mode to a α-γ-DA hybrid mode. This is ascribed to the enhanced ionization process of secondary electrons due to their sufficient collisions when the discharge region expands, as well as the weakened drift and ambipolar electric fields. By increasing the secondary electron emission coefficient, the number density of secondary electrons grows, and thus the discharge experiences a transition from a α-DA hybrid mode over a α-γ-DA hybrid mode and finally into the γ mode. Moreover, when the proportion of CF4 increases, the discharge tends to be more electronegative. As a consequence, the discharge gradually transits from a α-γ hybrid mode over a α-γ-DA hybrid mode, and finally to the DA mode. The results obtained in this work are important for improving the high aspect ratio etching process by secondary electrons.

Published

2022

36. Study on thermal shock irradiation resistance of CoCrFeMnNi high entropy alloy by high intensity pulsed ion beam

Author

Lisong Zhang, Xianxiu Mei, Na Li, Vladimir V. Uglov, Gennady E. Remnev, Xingzhong Cao, S. K. Pavlov, Eryang Lu, You-Nian Wang, Xiaonan Zhang, and Xiaona Li

Subjects

Nuclear and High Energy Physics, Thermal shock, Materials science, Lattice constant, Nuclear Energy and Engineering, Ion beam, High entropy alloys, Vacancy defect, General Materials Science, Irradiation, Composite material, Microstructure, Ion

Abstract

In recent years, high entropy alloys (HEAs) have attracted significant attention due to their excellent physical, chemical, mechanical properties, and good irradiation resistance, thus are considered as potential candidates for fission and fusion structural applications. CoCrFeMnNi HEA was irradiated by high intensity pulsed ion beam (HIPIB) to investigate the effects of thermal shock irradiation on their microstructure, surface morphology and mechanical properties. It was found that CoCrFeMnNi HEA maintained the face-centered cubic single-phase structure after HIPIB irradiation. The ion beam effect of irradiation produced numerous defects such as vacancies and stacking faults within the range of carbon ions. While the thermal effect reduced vacancy concentration beyond the ion range by promoting the recombination of vacancies with interstitials, and decreased the nano-hardness of CoCrFeMnNi HEA. The thermal effect and shock wave effect promoted the migration of vacancies and formed defects such as stacking faults etc. far beyond the ion range in CoCrFeMnNi HEA. Because of the very compositional complexity, the high-level chemical disorder and local lattice distortion of CoCrFeMnNi HEA, its lattice parameter was almost unchanged after HIPIB irradiation. Even if the temperature reached the melting point of CoCrFeMnNi HEA, there was no crack on the surface after surface remelting and rapid cooling. CoCrFeMnNi HEA showed good thermal stability and thermal shock irradiation resistance.

Published

2022

37. Hybrid simulation of instabilities in capacitively coupled RF CF4/Ar plasmas

Author

Wan Dong, Yi-Fan Zhang, Zhong-Ling Dai, Julian Schulze, Yuan-Hong Song, and You-Nian Wang

Subjects

Condensed Matter Physics

Abstract

Radio frequency capacitively coupled plasmas (RF CCPs) sustained in fluorocarbon gases or their mixtures with argon are widely used in plasma-enhanced etching. In this work, we conduct studies on instabilities in a capacitive CF4/Ar (1:9) plasma driven at 13.56 MHz at a pressure of 150 mTorr, by using a one-dimensional fluid/Monte-Carlo (MC) hybrid model. Fluctuations are observed in densities and fluxes of charged particles, electric field, as well as electron impact reaction rates, especially in the bulk. As the gap distance between the electrodes increases from 2.8 cm to 3.8 cm, the fluctuation amplitudes become smaller gradually and the instability period gets longer, as the driving power density ranges from 250 to 300 W m−2. The instabilities are on a time scale of 16–20 RF periods, much shorter than those millisecond periodic instabilities observed experimentally owing to attachment/detachment in electronegative plasmas. At smaller electrode gap, a positive feedback to the instability generation is induced by the enhanced bulk electric field in the highly electronegative mode, by which the electron temperature keeps strongly oscillating. Electrons at high energy are mostly consumed by ionization rather than attachment process, making the electron density increase and overshoot to a much higher value. And then, the discharge becomes weakly electronegative and the bulk electric field becomes weak gradually, resulting in the continuous decrease of the electron density as the electron temperature keeps at a much lower mean value. Until the electron density attains its minimum value again, the instability cycle is formed. The ionization of Ar metastables and dissociative attachment of CF4 are noticed to play minor roles compared with the Ar ionization and excitation at this stage in this mixture discharge. The variations of electron outflow from and negative ion inflow to the discharge center need to be taken into account in the electron density fluctuations, apart from the corresponding electron impact reaction rates. We also notice more than 20% change of the Ar+ ion flux to the powered electrode and about 16% difference in the etching rate due to the instabilities in the case of 2.8 cm gap distance, which is worthy of more attention for improvement of etching technology.

Published

2022

38. Nonlinear transmission line (NTL) model study of electromagnetic effects in high-frequency asymmetrically driven capacitive discharges

Author

Jian-Kai Liu, Emi Kawamura, Michael A. Lieberman, and You-Nian Wang

Subjects

Condensed Matter Physics

Published

2022

39. Two-dimensional fluid model of pulse sheath in plasma immersion ion implantation with dielectric substrates

Author

Xue-Chun, Li and You-Nian, Wang

Subjects

Dielectrics -- Properties, Plasma (Ionized gases) -- Models, Business, Chemistry, Electronics, Electronics and electrical industries

Abstract

A 2-D fluid model is developed to describe the charging effects during plasma immersion ion implantation with dielectric substrates. The spatiotemporal evolution of the surface potential, the accumulated charge dose, and the ion impact angle at the surface of dielectric substrates are calculated with the model. The numerical results demonstrate that the charging effects lead to reduction of the surface potential with time, and the surface potential is nonuniform along the dielectric surface. The lowest value of surface potential is near but not at the edge of the dielectric target. Therefore, the charge accumulation on the dielectric surface is also a function of surface position. The dose nonuniformity is more severe near the edge of the dielectric target. To lengthen the width of the metal electrode that is located below the dielectric target, one can improve the nonuniformity of the accumulated charge dose on the dielectric surface. Index Terms--Charging effects, plasma immersion ion implantation (PIII), sheath, 2-D fluid model.

Published

2007

40. The study of irradiation damage induced by proton in metallic glass Ni62Ta38 and metal W

Author

Yingmin Wang, Xianxiu Mei, Jianrong Sun, Xiaonan Zhang, and You-Nian Wang

Subjects

Nuclear and High Energy Physics, Materials science, Amorphous metal, Proton, Blisters, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Fluence, 010305 fluids & plasmas, Stress (mechanics), Metal, visual_art, 0103 physical sciences, medicine, Surface roughness, visual_art.visual_art_medium, Irradiation, medicine.symptom, Composite material, 0210 nano-technology, Instrumentation

Abstract

The protons with an energy of 250 keV were used to irradiate metallic glass Ni62Ta38 and metal W, the changes in structure and surface morphology of both the materials were compared, and their performances against the irradiation were evaluated, in order to provide the reference for the possibility of application of metallic glass Ni62Ta38 in irradiation environment. The results showed that after the proton irradiation, metallic glass Ni62Ta38 still maintained its good amorphousness without obvious irradiation damage on its surface. Meanwhile, stress was generated in metal W, and its crystalline size, micro-strain and dislocation line density varied undulately with the increase of fluence. When the irradiation fluence was 1.0 × 1018 ions/cm2, large area of blisters were formed on the surface of metal W. The surface roughness of metal W increased with the fluence. Compared with metal W, the proton irradiation resistance of metallic glass Ni62Ta38 was better.

Published

2018

41. The effect of He ions irradiation on the micro-structure and property of CLF-1 steel

Author

Pengfei Zheng, Jianrong Sun, Xianxiu Mei, Xingzhong Cao, Xiaonan Zhang, and You-Nian Wang

Subjects

Nuclear and High Energy Physics, Materials science, Blisters, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Fluence, 010305 fluids & plasmas, Amorphous solid, Carbide, Nuclear Energy and Engineering, Martensite, 0103 physical sciences, medicine, General Materials Science, Irradiation, medicine.symptom, Composite material, 0210 nano-technology, Dispersion (chemistry), Layer (electronics)

Abstract

The irradiation resistance of CLF-1 steel was investigated by using He ion irradiation with an energy of 300 keV. After the irradiation, the structure of CLF-1 steel mainly remained martensitic structure, while the lattice distortion and grain refinement occurred in the irradiation damaged layer. As irradiation fluence increased, the number of vacancies in CLF-1 steel increased, and the vacancies combined with the He atoms to form a bubble layer with the thickness of about 300 nm which located at the end of the He ions range. In the bubble layer, local amorphous region formed and the carbide particles showed a tendency to decompose. When the irradiation fluence was up to 1 × 1018ions/cm2, extensive blisters and a small amount of peelings appeared on the surface of CLF-1 steel. Due to grain refinement and dispersion of small carbide particles, the hardness of CLF-1 steel increased after the irradiation.

Published

2018

42. A comparative study of emissive probe techniques for vacuum space potential measurements

Author

Jian-quan Li, You-Nian Wang, Jun Xu, Wen-Qi Lu, and Fei Gao

Subjects

010302 applied physics, Materials science, Yield (engineering), Floating point, Volt, Condensed Matter Physics, Space (mathematics), 01 natural sciences, Measure (mathematics), Space charge, 010305 fluids & plasmas, Surfaces, Coatings and Films, Computational physics, General Relativity and Quantum Cosmology, Inflection point, 0103 physical sciences, Current (fluid), Instrumentation

Abstract

The major emissive probe techniques for the measurement of vacuum space potentials are compared to find the best emissive probe method in a vacuum. An overview of the inflection point method, the floating point method, and the vacuum current bias method is given, addressing how each method works in a vacuum. A comparison of the experimental data measured in a vacuum shows that the improved inflection point method has a best accuracy of 0.1 V in vacuum space potential measurements, while the original inflection point method can yield about half of a volt below the real space potential due to the inappropriate linear fitting in the method. Although the floating point method and the vacuum current bias method are convenient and rapid measurement techniques, the floating point method can only measure the vacuum potentials more than 1 V, and the space charge effect is not considered in the vacuum current bias method.

Published

2018

43. High-Intensity Pulsed Ion Beam Irradiation for Structural Stability of Metallic Glass Ni62Ta38

Author

Xianxiu Mei, Yingmin Wang, Xiaonan Zhang, You-Nian Wang, and Qi Zhang

Subjects

Nuclear and High Energy Physics, Materials science, Amorphous metal, Impulse (physics), Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Amorphous solid, Ion, Structural stability, 0103 physical sciences, Radiation damage, Thermal stability, Irradiation, Composite material, 010306 general physics

Abstract

Metallic glass Ni 62 Ta 38 was irradiated with the high-intensity pulsed ion beams (HIPIB) at an energy density of 0.32 J/cm 2 and different impulse times to study the structural thermal stability. Metallic glass Ni 62 Ta 38 remained an amorphous structure after HIPIB irradiation at different impulse times. However, the arrangement of atomic structure in the depth of about 700 nm from the surface of metallic glass became more disordered after irradiation. When the number of pulses increased to 300, a small amount of “bumps” appeared on the surface of the metallic glass, and no radiation damage such as cracks occurred. It shows that the metallic glass Ni 62 Ta 38 has good resistance to thermal damage from HIPIB irradiation and good structural stability.

Published

2018

44. Review of stopping power and Coulomb explosion for molecular ion in plasmas

Author

Yaochuan Wang, You-Nian Wang, Dajun Liu, Xing Wang, He Yi, Jieru Ren, Yujiao Li, Guiqiu Wang, Yongtao Zhao, Fei Gao, and Wei Liu

Subjects

Physics, Nuclear and High Energy Physics, Ion beam, Plasma parameters, Coulomb explosion, Plasma, 01 natural sciences, Diatomic molecule, Atomic and Molecular Physics, and Optics, 010305 fluids & plasmas, Ion, Nuclear Energy and Engineering, Physics::Plasma Physics, 0103 physical sciences, lcsh:QC770-798, Stopping power (particle radiation), lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, Electrical and Electronic Engineering, Atomic physics, 010306 general physics, Inertial confinement fusion

Abstract

We summarize our theoretical studies for stopping power of energetic heavy ion, diatomic molecular ions and small clusters penetrating through plasmas. As a relevant research field for the heavy ion inertial confinement fusion (HICF), we lay the emphasis on the dynamic polarization and correlation effects of the constituent ion within the molecular ion and cluster for stopping power in order to disclose the role of the vicinage effect on the Coulomb explosion and energy deposition of molecules and clusters in plasma. On the other hand, as a promising scheme for ICF, both a strong laser field and an intense ion beam are used to irradiate a plasma target. So the influence of a strong laser field on stopping power is significant. We discussed a large range of laser and plasma parameters on the coulomb explosion and stopping power for correlated-ion cluster and C60 cluster. Furthermore, in order to indicate the effects of different cluster types and sizes on the stopping power, a comparison is made for hydrogen and carbon clusters. In addition, the deflection of molecular axis for diatomic molecules during the Coulomb explosion is also given for the cases both in the presence of a laser field and laser free. Finally, a future experimental scheme is put forward to measure molecular ion stopping power in plasmas in Xi'an Jiaotong University of China. Keywords: Molecules, Stopping power, Coulomb explosion, Vicinage effect, Laser, PACS Codes: 34.50.Bw, 52.40.Mj, 61.85.+p, 34.50.Dy

Published

2018

45. Nonlocal electron kinetics and spatial transport in radio-frequency two-chamber inductively coupled plasmas with argon discharges.

Author

Hong Li, Yang Liu, Yu-Ru Zhang, Fei Gao, and You-Nian Wang

Subjects

ELECTRONS, RADIO frequency, ARGON, ELECTRON density, PLASMA sources

Abstract

A two-chamber inductively coupled plasma (ICP) system, in which an expansion region with large volume is attached to a main ICP (driver region with a small vessel), is investigated. In order to give a comprehensive knowledge of this kind of plasma source, the axially and radially resolved measurements of the electron density, effective electron temperature, and electron energy probability function (EEPF) for an argon discharge are systematically conducted by means of Langmuir probe for various powers and gas pressures. Moreover, a hybrid model within COMSOL Multiphysics is employed to validate the experimental results. It is found that the diffusion combined with the nonlocal electron kinetics plays a predominant role in two-chamber ICPs. Along the axial direction, both the electron density and the electron temperature peak at the center of the driver region and they decline towards both sides. The depletion of high-energy tails of EEPFs with axial distance demonstrates the cooling mechanism for energetic electrons in the expansion region. Along the radial direction, the spatial distribution of the electron density exhibits a bell shape for various powers and pressures. However, the radial distribution of the effective electron temperature varies gradually from a convex shape to a concave shape with increasing gas pressure, indicating the transition from nonlocal to local electron kinetics. [ABSTRACT FROM AUTHOR]

Published

2017

46. Fluid simulation of species concentrations in capacitively coupled N2/Ar plasmas: Effect of gas proportion.

Author

Ying-Shuang Liang, Gang-Hu Liu, Chan Xue, Yong-Xin Liu, and You-Nian Wang

Subjects

ELECTRON impact ionization, NITROGEN, GASES, SILICON nitride, DIELECTRIC function

Abstract

A two-dimensional self-consistent fluid model and the experimental diagnostic are employed to investigate the dependencies of species concentrations on the gas proportion in the capacitive N2/Ar discharges operated at 60 MHz, 50 Pa, and 140 W. The results indicate that the N2/Ar proportion has a considerable impact on the species densities. As the N2 fraction increases, the electron density, as well as the Ar+ and Arm densities, decreases remarkably. On the contrary, the N2+ density is demonstrated to increase monotonically with the N2 fraction. Moreover, the N density is observed to increase significantly with the N2 fraction at the N2 fractions below 40%, beyond which it decreases slightly. The electrons are primarily generated via the electron impact ionization of the feed gases. The electron impact ionization of Ar essentially determines the Ar+ density. For the N2+ production, the charge transition process between the Ar+ ions and the feed gas N2 dominates at low N2 fraction, while the electron impact ionization of N2 plays the more important role at high N2 fraction. At any gas mixtures, more than 60% Arm atoms are generated through the radiative decay process from Ar(4p). The dissociation of the feed gas N2 by the excited Ar atoms and by the electrons is responsible for the N formation at low N2 fraction and high N2 fraction, respectively. To validate the simulation results, the floating double probe and the optical emission spectroscopy are employed to measure the total positive ion density and the emission intensity originating from Ar(4p) transitions, respectively. The results from the simulation show a qualitative agreement with that from the experiment, which indicates the reliable model. [ABSTRACT FROM AUTHOR]

Published

2017

47. Control of radiation-driven tearing mode by externally driven current in tokamaks

Author

Hai-Wen Xu, Yuan-Hong Song, Zhi-Wei Ma, and You-Nian Wang

Subjects

Nuclear Energy and Engineering, Condensed Matter Physics

Abstract

The radiation-driven tearing mode (RTM) in tokamaks was numerically studied in our previous investigation (Xu et al 2020 Plasma Phys. Control. Fusion 62 105009), and it was noticed that radiation cooling could drive magnetic island growth and could even cause disruption due to the nonlinear mode coupling. In this work, the suppression of the radiation-driven m / n = 2 / 1 tearing mode by an externally driven current is investigated numerically by using a three-dimensional toroidal code CLT (Ci-Liu-Ti means magnetohydrodynamics in Chinese) based on a full set of resistive magnetohydrodynamic equations. It is found that an externally driven current with appropriate turn-on time and strength can effectively stabilize the RTM. The effects of the asymmetry current and multi-mode coupling can be stabilized effectively by the externally driven current. In the nonlinear stage, under the influence of the radiation, a strong m / n = 1 / 0 mode is generated due to the hot-core shift caused by the decrease of the core thermal pressure, which is irreversible even if the m / n = 2 / 1 magnetic island could be effectively controlled by the externally driven current. When the externally driven current is turned on in the linear stage, it very efficiently and quickly suppresses the dominant modes, and the hot-core shift effect also becomes weaker because of the smaller m / n = 1 / 0 mode. Moreover, it is found that external auxiliary heating with appropriate intensity in the core region can effectively balance the reduced pressure and can further control the hot-core shift caused by radiative cooling.

Published

2021

48. Radially-dependent ignition process of a pulsed capacitively coupled RF argon plasma over 300 mm-diameter electrodes: multi-fold experimental diagnostics

Author

Fei Gao, Kai Zhao, You-Nian Wang, Yong-Xin Liu, De-Hua Shi, and Su Zixuan

Subjects

Ignition system, Materials science, Argon, Fold (higher-order function), chemistry, law, Scientific method, Electrode, Analytical chemistry, chemistry.chemical_element, Plasma, Condensed Matter Physics, law.invention

Abstract

A synergistic combination of multi-diagnostic methods are proposed to investigate temporal evolution of electrical and plasma parameters at various radial positions over 300 mm-diameter electrodes during the pre-ignition, ignition, and post-ignition phases of a pulsed capacitively coupled radio-frequency (RF) argon discharge. The electron density, n e, and the optical emission intensity (OEI) of argon at 750.4 nm at different radial positions are measured time-resolved by using a hairpin probe and an optical probe, respectively. A B-dot probe is employed to determine the waveforms of the azimuthal magnetic field at different radii, from which the waveforms of the axial current density at corresponding radial positions are derived based on Ampere’s law. Then, the time evolution of the power density at various radii can be calculated, provided that the voltage drop between the electrodes is independent of radius. Meanwhile, the time-dependent total power deposited into the reactor is calculated with the voltage and the current waveforms measured by a voltage and a current probe at the power feeding point. It was found that during pre-ignition phase, the OEI and n e cannot be measurable due to extremely low power deposition when the system exhibits pure capacitive impedance. During the ignition phase, the OEI, the power density, and the current density exhibit the most significant increase at the electrode center, while the time evolution of n e measured by the hairpin probe seems to exhibit a relatively weak radial dependence during this phase. In particular, at r ⩽ 8 cm, the OEI at every radius was observed to change with time in the same manner as the power density during the ignition phase, because the RF power is absorbed primarily by electrons, which dissipate their energy via inelastic collisions. Shortly, the profile of n e becomes edge-high during the post-ignition phase and remains thereafter until the end of the pulse-on period. Methodologically, the synergistic diagnostics lay the foundation for extensive studies on spatiotemporal evolution of plasma ignition process under broader conditions, e.g. electronegative gas, lower working gas pressure and very high driving frequency, widely used by practical etching process.

Published

2021

49. Simulation of nonlinear standing wave excitation in very-high-frequency asymmetric capacitive discharges: roles of radial plasma density profile and rf power

Author

You-Nian Wang, Jian-Kai Liu, Yong-Xin Liu, Kai Zhao, De-Qi Wen, and Fang-Jie Zhou

Subjects

Standing wave, Physics, Nonlinear system, Computer Science::Information Retrieval, Capacitive sensing, RF power amplifier, Very high frequency, Condensed Matter Physics, Excitation, Plasma density, Computational physics

Abstract

It is recognized that in large-area, very-high-frequency capacitively coupled plasma (VHF CCP) reactors, the higher harmonics generated by nonlinear sheath motion can lead to enhanced standing wave excitation. In this work, a self-consistent electromagnetic model, which couples a one-dimensional, radial nonlinear transmission line model with a bulk plasma fluid model, is employed to investigate the nonlinear standing wave excitation in a VHF driven, geometrically asymmetric capacitive argon discharge operated at low pressure. By considering a radially non-uniform plasma density profile (case I) calculated self-consistently by the nonlinear electromagnetic model and the corresponding radially-averaged, uniform plasma density profile (case II), we first examine the effect of the plasma density non-uniformity on the propagation of electromagnetic surface waves in a 3 Pa argon discharge driven at 100 MHz and 90 W. Compared to case II, the higher plasma density at the radial center in case I determines a higher plasma series resonance frequency, yielding stronger high-order harmonic excitations and more significant central peak in the harmonic current density J z,n and the harmonic electron power absorption p n profiles. Therefore, under the assumption of the radially uniform plasma density in a CCP discharge, the self-excitation of higher harmonics at the radial center should be underestimated. Second, using the self-consistent electromagnetic model, the effect of the rf power on the excitation of nonlinear standing waves is investigated in a 3 Pa argon discharge driven at 100 MHz. At a low power of 30 W, the discharge is dominated by the first two harmonics. The higher harmonic excitations and the nonlinear standing waves are observed to be enhanced with increasing the rf power, resulting in a more pronounced central peak in the radial profiles of the total electron power absorption density p e, the electron temperature T e, and the electron density n e. For all rf powers, the calculated radial profiles of n e show good agreement with the experimental data obtained by a floating double probe.

Published

2021

50. X-ray beams produced by hot electrons with directional drift velocity in fusion plasmas

Author

De-Xuan Hui, Xianxiu Mei, Zhang-Hu Hu, Wan-Li Shang (尚万里), and You-Nian Wang

Subjects

Physics, Linear function (calculus), Drift velocity, Distribution (mathematics), Nuclear Energy and Engineering, Logarithm, Numerical analysis, Bremsstrahlung, Plasma, Condensed Matter Physics, Spectral line, Computational physics

Abstract

Spectra and emission efficiencies of x-rays produced by hot electrons (hot-e’s) with drift Maxwellian distribution are studied using both analytical and numerical methods. The analytic expressions are particularly useful for the analysis of x-ray spectra produced by hot-e’s in laser-produced plasma. Both analytical and numerical results show that when hot-e’s have a nonzero drift velocity, the bremsstrahlung spectrum is still approximately a linear function in logarithmic coordinates, which indicates that the process of inferring hot-e’s temperature from the slope of x-ray spectrum needs to be revisited under certain circumstances.

Published

2021