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Li SUN, Zhuo DAI, Ming XU, Wei WANG, Zengyao LI. Analysis of application range of simplified models for field to thermo-field to thermionic emission processes from the cathode[J]. Plasma Science and Technology, 2024, 26(9): 094005. DOI: 10.1088/2058-6272/ad4cad
Citation: Li SUN, Zhuo DAI, Ming XU, Wei WANG, Zengyao LI. Analysis of application range of simplified models for field to thermo-field to thermionic emission processes from the cathode[J]. Plasma Science and Technology, 2024, 26(9): 094005. DOI: 10.1088/2058-6272/ad4cad

Analysis of application range of simplified models for field to thermo-field to thermionic emission processes from the cathode

  • Electron emission plays a dominant role in plasma–cathode interactions and is a key factor in many plasma phenomena and industrial applications. It is necessary to illustrate the various electron emission mechanisms and the corresponding applicable description models to evaluate their impacts on discharge properties. In this study, detailed expressions of the simplified formulas valid for field emission to thermo-field emission to thermionic emission typically used in the numerical simulation are proposed, and the corresponding application ranges are determined in the framework of the Murphy–Good theory, which is commonly regarded as the general model and to be accurate in the full range of conditions of the validity of the theory. Dimensionless parameterization was used to evaluate the emission current density of the Murphy–Good formula, and a deviation factor was defined to obtain the application ranges for different work functions (2.5‒5 eV), cathode temperatures (300‒6000 K), and emitted electric fields (105 to 1010 V·m−1). The deviation factor was shown to be a nonmonotonic function of the three parameters. A comparative study of particle number densities in atmospheric gas discharge with a tungsten cathode was performed based on the one-dimensional implicit particle-in-cell (PIC) with the Monte Carlo collision (MCC) method according to the aforementioned application ranges. It was found that small differences in emission current density can lead to variations in the distributions of particle number density due to changes in the collisional environment. This study provides a theoretical basis for selecting emission models for subsequent numerical simulations.
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