Investigation of the Start Transient in a Hall Thruster

Liu, H.; Yu, Daren; Yan, Guirong; Liu, J. Y.

doi:10.1002/ctpp.200810094

Cited by 30 publications

(30 citation statements)

References 16 publications

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“…The results resemble simulations reported previously [1,2]. PIC simulations reveal strongly peaked (8x-10x steadystate mean) density and current before entering stable operation at 50 µs [2].…”

supporting

confidence: 87%

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Fast Camera Imaging of Hall Thruster Ignition

Ellison

Raitses

Fisch

2011

IEEE Trans. Plasma Sci.

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supporting

confidence: 87%

“…Recently, 2-D particle-in-cell codes have modeled plasma density, potential, and current during the ignition phase [1,2], but limited experimental evidence is available for comparison [3]. Here we contribute time-resolved images of the thruster ignition, revealing azimuthal spatial structure and an intensity peak lasting for an ionization-relevant timescale.…”

mentioning

confidence: 99%

Fast Camera Imaging of Hall Thruster Ignition

Ellison

Raitses

Fisch

2011

IEEE Trans. Plasma Sci.

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“…19 It also can be seen that models with expanding-angle have a higher maximum value of efficiency and impulse, while the optimal operating states are at larger mass flow rate.…”

Section: Aip Advances 8 045019 (2018)mentioning

confidence: 91%

“…It is known that compared with Hall thrusters, the cusped field thrusters start up with a relatively small ignition voltage and they are free from current impact (an instantaneous anode current peak in ignition, which would have an impact on power supply modules, usually in Hall thrusters). 19 In terms of physical mechanism, a central leak path in the channel was found in our recent Particle-in-Cell simulation, through which some electrons can arrive at the anode along the thruster centerline and give rise to the ignition at a relative low discharge voltage. 20 In the ignition process, the source electrons have to overcome the magnetic mirror outside the channel exit during a startup period in cusped field thrusters.…”

Section: A Start Up and Operation Spacementioning

confidence: 93%

Experimental investigation of the effects of variable expanding channel on the performance of a low-power cusped field thruster

et al. 2018

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Due to a special magnetic field structure, the multi-cusped field thruster shows advantages of low wall erosion, low noise and high thrust density over a wide range of thrust. In this paper, expanding discharge channels are employed to make up for deficiencies on the range of thrust and plume divergence, which often emerges in conventional straight cylindrical channels. Three thruster geometries are fabricated with different expanding-angle channels, and a group of experiments are carried out to find out their influence on the performance and discharge characteristics of the thruster. A retarding potential analyzer and a Faraday probe are employed to analyze the structures of the plume in these three models. The results show that when the thrusters operate at low mass flow rate, the gradually-expanding channels exhibit lower propellant utilization and lower overall performance by amounts not exceeding 44.8% in ionization rate and 19.5% in anode efficiency, respectively. But the weakening of magnetic field intensity near the exit of expanding channels leads to an extended thrust throttling ability, a smaller plume divergence angle, and a relatively larger stable operating space without mode converting and the consequent performance degradation.

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“…The PIC codes in our lab have been used in many other studies including ignition processes, near wall transportation, double stage Hall thruster, oscillation sheath and et al [13][14][15][16] These methods employ particle-in-cell with Monte-Carlo methods to deal with collision between ions and electrons. The model 14 is 2D-3V cylindrical coordinate and contains r, z, v (r,z,θ) .…”

Section: A the Pic Methods And The Simulation Of Thruster Modelmentioning

confidence: 99%

Magnetic field deformation due to electron drift in a Hall thruster

Han

Ding

et al. 2017

AIP Advances

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The strength and shape of the magnetic field are the core factors in the design of the Hall thruster. However, Hall current can affect the distribution of static magnetic field. In this paper, the Particle-In-Cell (PIC) method is used to obtain the distribution of Hall current in the discharge channel. The Hall current is separated into a direct and an alternating part to calculate the induced magnetic field using Finite Element Method Magnetics (FEMM). The results show that the direct Hall current decreases the magnetic field strength in the acceleration region and also changes the shape of the magnetic field. The maximum reduction in radial magnetic field strength in the exit plane is 10.8 G for an anode flow rate of 15 mg/s and the maximum angle change of the magnetic field line is close to 3° in the acceleration region. The alternating Hall current induces an oscillating magnetic field in the whole discharge channel. The actual magnetic deformation is shown to contain these two parts.

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Investigation of the Start Transient in a Hall Thruster

Cited by 30 publications

References 16 publications

Fast Camera Imaging of Hall Thruster Ignition

Fast Camera Imaging of Hall Thruster Ignition

Experimental investigation of the effects of variable expanding channel on the performance of a low-power cusped field thruster

Magnetic field deformation due to electron drift in a Hall thruster

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