Effects of Optical Pulse Parameters on a Pulsed UV-Illuminated Switch and Their Adjusting Methods

Li, Junna; Chen, Weiqing; Chen, Zhiqiang; Tang, Junping; Jia, Wei; Guo, Fan; Yang, Tian; Qiu, Aici; Zhao, Junping; Zhang, Qiaogen

doi:10.1109/tps.2015.2457955

Cited by 11 publications

(20 citation statements)

References 10 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It is important to note how the pre-ionization works [5], [15]. From Figure 1(c) we can see that the main gap electric field is designed to be shielded at the trigger gap, and it is impossible that the electrons in the arc channel of the trigger gap lead to an electron avalanche and breakdown of the main gap.…”

Section: B Pre-ionized Breakdown Characteristicsmentioning

confidence: 99%

“…From Figure 1(c) we can see that the main gap electric field is designed to be shielded at the trigger gap, and it is impossible that the electrons in the arc channel of the trigger gap lead to an electron avalanche and breakdown of the main gap. Considering that the first ionization energy of nitrogen molecule is about 15.5eV, and the photon's energy is in the range of 3.1eV to 3.9eV [15], so it is also impossible that photons generated by spark discharge will ionize the nitrogen molecules and initiate an electron avalanche near the trigger gap. The work function of stainless steel is about 4.4eV, but the photons are generated when the electric field strength at the cathode surface is high enough, the actual work function will be smaller than 4.4eV.…”

Section: B Pre-ionized Breakdown Characteristicsmentioning

confidence: 99%

“…Effective UV illumination started to appear when the trigger gap broke down. Initial electrons in the main gap generated by cathode photoemission mainly appeared when UV illumination appeared, and UV illumination only sustained for a short period, not during the whole spark discharge process [15], so the initial electrons could only appear during a specific time. It should be specially noted that the electrons in the arc channel of the trigger gap could not drift towards the main gap anode (and become initial electrons) because the trigger plane shielded the main gap electric field at the trigger gap.…”

Section: B Pre-ionized Breakdown Characteristicsmentioning

confidence: 99%

“…To explain why pre-ionization under low gas pressure was ineffective, the ability of initial electrons with different generating times and numbers to initiate an electron avalanche should be analyzed. The probability model [18] and diagnosis results [15] are used for reference in this section to analyze the influence of generating time and rate of initial electrons on the pre-ionization effect.…”

Section: Influence Mechanism Of Pre-ionizationmentioning

confidence: 99%

“…Diagnosis results indicate that the rise time of UV optical pulse was smaller than 5ns when the trigger gap had a slightly non-uniform field, and FWHM of UV optical pulse was smaller than 15ns when there was no energy storage capacitor (Cs) in parallel with the gap [15]. The typical waveform of the UV optical pulse (central wavelength 337 nm) is shown in Figure 10 [15].…”

Section: B Influence Of Generating Time and Rate Of Initial Electronsmentioning

confidence: 99%

See 4 more Smart Citations

Optimization of a Nanosecond Pre-Ionization Switch’s Breakdown Jitter Characteristic Based on a Probability Distribution Model of Electron Avalanche’s Initiation

Wang

Chen

et al. 2021

IEEE Access

View full text Add to dashboard Cite

The breakdown jitter characteristic of a self-triggered pre-ionization switch that works under pulses with the rising time of about one hundred nanoseconds was improved based on the probability distribution model of electron avalanche's initiation. Contrary to what we might imagine, premature pre-ionization nearly brought about no improvement on the breakdown jitter characteristic. To reduce the switch jitter, analysis of the probability distribution model indicated that the generating rate of initial electrons should maintain a high value when the electric field in the gap was high enough to initiate an effective electron avalanche. Experimental results proved that adjusting the breakdown time of the trigger gap or letting the electrons in the arc channel of the trigger gap become a steady source of initial electrons could both reduce the breakdown time delay jitter to 1ns-2ns when the breakdown time was about 95% of the peak time, this means that high energy transfer efficiency and low jitter were realized simultaneously.INDEX TERMS Gas switch, nanosecond pulse, pre-ionization, self-triggering, time delay jitter.

show abstract

Section: B Pre-ionized Breakdown Characteristicsmentioning

confidence: 99%

Section: B Pre-ionized Breakdown Characteristicsmentioning

confidence: 99%

Section: B Pre-ionized Breakdown Characteristicsmentioning

confidence: 99%

Section: Influence Mechanism Of Pre-ionizationmentioning

confidence: 99%

Section: B Influence Of Generating Time and Rate Of Initial Electronsmentioning

confidence: 99%

See 3 more Smart Citations

Optimization of a Nanosecond Pre-Ionization Switch’s Breakdown Jitter Characteristic Based on a Probability Distribution Model of Electron Avalanche’s Initiation

Wang

Chen

et al. 2021

IEEE Access

View full text Add to dashboard Cite

show abstract

Experimental investigation and theoretical analysis of the breakdown time delay and jitter of multi-gap gas switch gaps

Wen,

Wang,

Fan

et al. 2023

Review of Scientific Instruments

View full text Add to dashboard Cite

The gas gap of a multi-gap gas switch can be classified as trigger and self-breakdown gaps based on the breakdown condition. A two-gap gas switch consisting of a trigger gap and a self-breakdown gap is developed to independently study the breakdown characteristics of these two types of switch gaps. Trigger experiments for the switch are conducted under various trigger voltage rise rates and different working coefficients. The experimental results indicate that the trigger gap has significantly more jitter than the self-breakdown gap, and the overall performance of the gas switch is determined primarily by the trigger gap. A novel pre-ionization structure with disks is implemented into the two-gap gas switch, considerably decreasing the breakdown delay of the trigger gap and reducing the jitter to a quarter or even less compared to that without pre-ionization. A calculation model of the breakdown time delay for the trigger gap is provided based on the foundational development of the avalanche. The probability distribution of the time required for the initial electron generation is derived in the absence of pre-ionization. The calculated breakdown time delay agrees well with the experimental results in cases with and without pre-ionization under most trigger settings. The method and principle of calculating the breakdown time delay can analyze the collapse of a gas gap with different electrode configurations (quasi-uniform or uniform electrical fields) and various gas media under a nanosecond pulse voltage.

show abstract

Analysis on discharge process of a plasma-jet triggered gas spark switch

Tie¹,

Meng²,

Zhang³

et al. 2017

Plasma Sci. Technol.

Self Cite

View full text Add to dashboard Cite

The plasma-jet triggered gas switch (PJTGS) could operate at a low working coefficient with a low jitter. We observed and analyzed the discharge process of the PJTGS at the lowest working coefficient of 47% with the trigger voltage of 40 kV and the pulse energy of 2 J to evaluate the effect of the plasma jet. The temporal and spatial evolution and the optical emission spectrum of the plasma jet were captured. And the spraying delay time and outlet velocity under different gas pressures were investigated. In addition, the particle in cell with Monte Carlo collision was employed to obtain the particle distribution of the plasma jet varying with time. The results show that, the plasma jet generated by spark discharge is sprayed into a spark gap within tens of nanoseconds, and its outlet velocity could reach 10 4 m s −1 . The plasma jet plays a non-penetrating inducing role in the triggered discharge process of the PJTGS. On the one hand, the plasma jet provides the initial electrons needed by the discharge; on the other hand, a large number of electrons focusing on the head of the plasma jet distort the electric field between the head of the plasma jet and the opposite electrode. Therefore, a fast discharge originated from the plasma jet is induced and quickly bridges two electrodes.

show abstract

Effects of Optical Pulse Parameters on a Pulsed UV-Illuminated Switch and Their Adjusting Methods

Cited by 11 publications

References 10 publications

Optimization of a Nanosecond Pre-Ionization Switch’s Breakdown Jitter Characteristic Based on a Probability Distribution Model of Electron Avalanche’s Initiation

Optimization of a Nanosecond Pre-Ionization Switch’s Breakdown Jitter Characteristic Based on a Probability Distribution Model of Electron Avalanche’s Initiation

Experimental investigation and theoretical analysis of the breakdown time delay and jitter of multi-gap gas switch gaps

Analysis on discharge process of a plasma-jet triggered gas spark switch

Contact Info

Product

Resources

About