Analysis and observation of spacecraft plume/ionosphere interactions during maneuvers of the space shuttle

Stephani, Kelly A.; Boyd, Iain D.; McHarg, M. G.; Mueller, Brandon; Adams, Richard J.

doi:10.1002/2013ja019476

Cited by 9 publications

(5 citation statements)

References 20 publications

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“…However, in practical applications, it is found that the electric thruster plume will bring great harm to the spacecraft, and even lead to spacecraft failure. For example, Charge Exchange (CEX) ions of the plume can bring thermal loads and pollute electronic components of the spacecraft (1)(2)(3) . Therefore, how to reduce the impact of the plume on the spacecraft is critical to the future application of electric thrusters.…”

Section: Introductionmentioning

confidence: 99%

A 3D particle model for the plume CEX simulation

Qiu

Cao

et al. 2018

Aeronaut. j.

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Charge Exchange (CEX) ion is the main factor causing the plume pollution. The distribution of CEX ions is determined by the distribution of beam ions and neutral atoms. Hence, the primary problem in the study of the plume is how to accurately simulate the distribution of beam ions and neutral atoms. At present, the most commonly used model utilised for the plume simulation is the analytical model proposed by Roy for the plume simulation of the NASA Solar Technology Application Readiness (NSTAR) ion thruster. However, this analytical model can only be applied to the ion beam with small divergence angles. In addition, the analytical model is no longer applicable to the simulation for the plume of a new type of ion thruster that appeared recently, which is called the annular ion thruster. In this paper, a 3D particle model is proposed for the plume simulation of ion thrusters consisting of the particle model for beam ions, the Direct Simulation Monte Carlo (DSMC) model for neutral atoms and the Immersed Finite Element-Particle In Cell-Monte Carlo Collision (IFE-PIC-MCC) model for CEX ions. Then, the plume of the NSTAR ion thruster is simulated by both Roy's model and the 3D particle model. The simulation results of both models are then compared with the experimental results. It is shown that the numerical results of the 3D particle model agree well with those of the analytical model and the experimental data. And this 3D particle model can also be used for other electric thrusters.

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Section: Introductionmentioning

confidence: 99%

A 3D particle model for the plume CEX simulation

Qiu

Cao

et al. 2018

Aeronaut. j.

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“…2,3 This methodology has also been applied to the Space Shuttle rocket plume expansion into the ionosphere to explain the correlation between rocket firings and measured ion fluxes aboard the international space station (ISS). 4 Several others [5][6][7] have also investigated the interactions between spacecraft, rocket plumes, and the space environment, but are focused on interactions at LEO. The lower densities, higher energies of ambient ions, and lower geomagnetic field strength at GEO relative to LEO changes the relative importance of the various plume-atmosphere interactions, and therefore a separate analysis is required to better understand and predict plume behavior at GEO.…”

Section: Introductionmentioning

confidence: 99%

Unsteady Simulations of Rocket Plume Expansions in Geostationary Earth Orbit

Weaver

Boyd²

2017

Journal of Spacecraft and Rockets

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Unsteady, direct simulation Monte Carlo (DSMC)-particle-in-cell (PIC) simulations of rocket plume expansions into the magnetosphere at geostationary Earth orbit (GEO) are presented for three rocket thruster pulse durations: 0.1 s, 1.4 s, and 9.9 s. The chemical rocket thruster ejects hydrazine combustion products at a mass flow rate of 4.5 × 10 −4 kg/s, and the number densities are computed as a function of time for distances up to 35 km from the rocket thruster. The plume reaches steady-state operation 1 km downstream of the rocket thruster before the thruster is shut off at 1.4 s, and steady-state operation is reached as far as 20 km downstream of the rocket thruster for the 9.9 s pulse duration. An analytic expression for free-molecular flow expanding into a vacuum is compared to the unsteady simulations for number densities, and the influences of energetic protons and electrons emitted from the Sun on predicted total number densities are investigated.

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“…Incorporating these effects is critical for capturing the development of the spacecraft plume in the plasma environment, particularly over large distances. Recent efforts [ Stephani and Boyd , ; Stephani et al , ] investigating spacecraft plumes in low Earth orbit (LEO) have demonstrated that interaction of the spacecraft neutral plume with the ambient plasma forms a relatively high‐density spacecraft ion plume. The propagation of this ion plume is determined primarily by the interaction with the magnetic field, but the development of the neutral spacecraft plume is also affected (albeit indirectly) by the magnetic field interaction owing to secondary charge‐exchange reactions.…”

Section: Introductionmentioning

confidence: 99%

“…The present study aims to examine the interaction between spacecraft hydrazine thruster plumes and the ambient magnetosphere in geostationary Earth orbit (GEO) conditions. While previous efforts have developed a combined direct simulation Monte Carlo/particle‐in‐cell (DSMC/PIC) methodology to examine plumes in LEO [ Stephani and Boyd , ; Stephani et al , ], this study focuses on the additional physical model considerations involving nonequilibrium plasma mixtures. The rarefied nature of the magnetosphere, as well as the presence of the surrounding plasma environment, requires the use of a combined DSMC/PIC methodology, which is detailed next.…”

Section: Introductionmentioning

confidence: 99%

Spacecraft plume interactions with the magnetosphere plasma environment in geostationary Earth orbit

Stephani

Boyd

2016

JGR Space Physics

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Particle‐based kinetic simulations of steady and unsteady hydrazine chemical rocket plumes are presented in a study of plume interactions with the ambient magnetosphere in geostationary Earth orbit. The hydrazine chemical rocket plume expands into a near‐vacuum plasma environment, requiring the use of a combined direct simulation Monte Carlo/particle‐in‐cell methodology for the rarefied plasma conditions. Detailed total and differential cross sections are employed to characterize the charge exchange reactions between the neutral hydrazine plume mixture and the ambient hydrogen ions, and ion production is also modeled for photoionization processes. These ionization processes lead to an increase in local plasma density surrounding the spacecraft owing to a partial ionization of the relatively high‐density hydrazine plume. Results from the steady plume simulations indicate that the formation of the hydrazine ion plume are driven by several competing mechanisms, including (1) local depletion and (2) replenishing of ambient H+ ions by charge exchange and thermal motion of 1 keV H+ from the ambient reservoir, respectively, and (3) photoionization processes. The self‐consistent electrostatic field forces and the geostationary magnetic field have only a small influence on the dynamics of the ion plume. The unsteady plume simulations show a variation in neutral and ion plume dissipation times consistent with the variation in relative diffusion rates of the chemical species, with full H2 dissipation (below the ambient number density levels) approximately 33 s after a 2 s thruster burn.

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Analysis and observation of spacecraft plume/ionosphere interactions during maneuvers of the space shuttle

Cited by 9 publications

References 20 publications

A 3D particle model for the plume CEX simulation

A 3D particle model for the plume CEX simulation

Unsteady Simulations of Rocket Plume Expansions in Geostationary Earth Orbit

Spacecraft plume interactions with the magnetosphere plasma environment in geostationary Earth orbit

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