Simulation of Potential Measurements Around a Photoemitting Spacecraft in a Flowing Plasma

Author

Sjögren, Alexander ; Eriksson, Anders I. ; Cully, Christopher M.

Author_Institution

ERAU, Daytona Beach, FL, USA

Volume

40

Issue

4

fYear

2012

fDate

4/1/2012 12:00:00 AM

Firstpage

1257

Lastpage

1261

Abstract

Plasma measurements by electrostatic probes are influenced by the spacecraft-plasma interaction, including the photoelectrons emitted by the spacecraft. Such effects get particularly important in tenuous plasmas with large Debye lengths. We have used the particle-in-cell code package SPIS to study the close environment of the Rosetta spacecraft, and the impact of the spacecraft-plasma interaction on the electrostatic potential at the position of the Langmuir probes onboard. The simulations show that in the solar wind, photoemission has a bigger impact than wake formation. Spacecraft potential estimates based on Langmuir probe data in the solar wind need to be compensated for these effects when the spacecraft attitude varies. The SPIS simulations are validated by comparison to an independent code.

Keywords

Langmuir probes; astrophysical plasma; electrostatics; photoemission; plasma flow; plasma simulation; solar wind; space vehicles; spacecraft charging; Debye lengths; Langmuir probe data; Langmuir probe position; Rosetta spacecraft; SPIS simulations; electrostatic potential; electrostatic probes; flowing plasma; particle-in-cell code package SPIS; photoelectrons; photoemission; photoemitting spacecraft; plasma measurements; potential measurement simulation; solar wind; spacecraft attitude; spacecraft potential; spacecraft-plasma interaction; wake formation; Computational modeling; Electric potential; Photoelectricity; Plasma measurements; Plasmas; Probes; Space vehicles; Rosetta mission; SPIS; spacecraft charging;

fLanguage

English

Journal_Title

Plasma Science, IEEE Transactions on

Publisher

ieee

ISSN

0093-3813

Type

jour

DOI

10.1109/TPS.2012.2186616

Filename

6165377