Effects of the tube diameter on the propagation of helium plasma plume via electric field measurement

Wu, Shuqun; Lü, Xinpei; Yue, Yuanfu; Dong, Xiangcheng; Pei, Xiaobing

doi:10.1063/1.4964280

Cited by 44 publications

(51 citation statements)

References 32 publications

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“…They observed that the streamer velocity increases first and then decreases after reaching a peak at the tube diameter of 200 µm . In our previous work, for a He streamer propagating inside a tube, as the tube diameter decreases from 4 to 0.6 mm, the streamer velocity increases first and then decreases after reaching a peak at the tube diameter of 1 mm . These results are similar to our case.…”

Section: Discussionsupporting

confidence: 91%

“…This also agrees well with the observation of the corona‐like air plasma for smaller capillaries in Figure . Similar behavior has been observed in our previous work, where the electric field strength in the head of the ionization front increases from 9 to 20 kV cm −1 for the tube diameter decreasing from 4 to 0.6 mm. The electric field in front of the ionization wave is composed of the external electric field and the local electric field induced by the charges.…”

Section: Discussionsupporting

confidence: 90%

“…To understand the effects of the tube diameter, several research groups have made great efforts in previous works . As the tube diameter decreases from several mm to 80 µm, the significant increase of the ignition voltage, the current density, the electric field, and the electron density is observed . Meanwhile, the gas temperature is weakly dependent on the tube diameter .…”

Section: Introductionmentioning

confidence: 99%

“…The numerical simulation results reveal that the increase of the ignition voltage with the reduction of the tube diameter is caused by the decrease of the seed electron density . Moreover, using a high‐speed imaging technique, as the tube diameter is further reduced to 70 µm, the propagation of the helium (He) microplasma plume converts from a discrete “plasma bullet” mode to a continuous plasma column mode . In the front view of the plasma volume, when the tube diameter decreases, the discharge transits from a donut‐shaped mode to a contracted mode .…”

Section: Introductionmentioning

confidence: 99%

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The effects of the tube diameter on the discharge ignition and the plasma properties of atmospheric‐pressure microplasma confined inside capillary

Liu

et al. 2019

Plasma Processes & Polymers

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With plasma penetration into a capillary and the assistant of an air DBD, an ac‐driven Ar microplasma plume having a length of several cm is generated inside the capillary. The inner diameter of the capillary ranges from 4 to 100 µm. When the tube diameter decreases, the length of the microplasma plume decreases, and while the ignition voltage, the current density, and the electron density increase significantly. For the tube diameter of 9 µm, the current density and the electron density measured from the Stark broadening of Hα line reach as high as 109 A m−2 and 11 × 1016 cm−3, respectively. The microplasma plume is of high degree of ionization and remains non‐thermal. Rather than monotonically increasing, the propagation velocity of the microplasma plume decreases and then keeps almost unchanged after the tube diameter reaches 20 µm.

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Section: Discussionsupporting

confidence: 91%

Section: Discussionsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

The effects of the tube diameter on the discharge ignition and the plasma properties of atmospheric‐pressure microplasma confined inside capillary

Liu

et al. 2019

Plasma Processes & Polymers

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“…We were able to point in this way that, for constant flow rate conditions and fixed electrode arrangement, the length of the outside jet depends on the frequency and amplitude of the driving high voltage pulses ( Figure 6). Supplementary, it has been demonstrated in a number of recent studies, that this characteristic dimension of the outside plasma jets in helium is also influenced by the electrodes dimensions and constructive details [40,41], gas flow rate [38,[42][43][44], dielectric tube diameter [45][46][47].…”

Section: Plasma Source Quasi-stationary Working Regimementioning

confidence: 99%

Time Behaviour of Helium Atmospheric Pressure Plasma Jet Electrical and Optical Parameters

et al. 2017

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Low temperature plasma jets gained increased interest in the last years as a potential device in many life science applications, including here human or veterinary medicine. Standardisation of plasma sources and biological protocols are necessary for quality assurance reasons, due to the fact that this type of atmospheric pressure plasma source is available in multiple configurations and their operational parameters span also on a broad range of items, such as all characteristics of high voltage pulses used for gas breakdown, geometrical characteristics, gas feed composition and conductive or biological target characteristics. In this paper we present results related to electrical, optical and molecular beam mass spectrometry diagnosis of a helium plasma jet, emphasising the influence of various operational parameters of the high voltage pulses on plasma jet properties. Discussion on physical parameters that influence the biological response is included, together with important results on plasma sources statistical behaviour until reaching a quasi-stationary working regime. The warm-up period of the plasma jet, specific to many other plasma sources, must be precisely known and specified whenever the plasma jets are used as a tool for life science applications.

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Comparison of two cold atmospheric pressure plasma jet configurations in argon

Jõgi

Talviste

Raud

et al. 2020

Contributions to Plasma Physics

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The present study compares the operation of two cold atmospheric plasma jet (CAPJ) configurations: needle‐to‐cylinder electrode configuration (CAPJ I) and single high‐voltage cylinder electrode around the quartz tube (CAPJ II). The CAPJs were operated in argon flowing through a quartz capillary with 0.5‐mm inner diameter into the ambient air, and the plasma was generated by sinusoidal kHz frequency AC power supplies. The main emphasis of the study was on the mechanism of the initiation of ionization waves for these two configurations. For both CAPJs, there appeared several ionization waves during one half‐period of the applied voltage waveform, and the number of ionization waves increased at higher voltage amplitudes. However, we discovered marked differences in the initiation of the ionization waves for two different CAPJ configuration. The applied voltage controlled the initiation of consecutive ionization waves, which propagated from the grounded electrode towards the tube orifice in CAPJ I. In the case of CAPJ II, certain time had to pass for the initiation of a new ionization wave, and subsequent ionization waves within the same half‐period started at the tube orifice. In addition to the differences in the initiation of the ionization waves, we observed that the CAPJ I was ignited and sustained at lower voltages, while CAPJ II produced a longer plasma jet. The observed advantages and deficiencies of investigated CAPJ configurations point out their potential in different applications.

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Effects of the tube diameter on the propagation of helium plasma plume via electric field measurement

Cited by 44 publications

References 32 publications

The effects of the tube diameter on the discharge ignition and the plasma properties of atmospheric‐pressure microplasma confined inside capillary

The effects of the tube diameter on the discharge ignition and the plasma properties of atmospheric‐pressure microplasma confined inside capillary

Time Behaviour of Helium Atmospheric Pressure Plasma Jet Electrical and Optical Parameters

Comparison of two cold atmospheric pressure plasma jet configurations in argon

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