Current‐induced magnetic field effects on bare tether current collection: A parametric study

Khazanov, G. V.; Stone, N. H.; Krivorutsky, E. N.; Gamayunov, K. V.; Liemohn, Michael W.

doi:10.1029/2000ja000345

Cited by 11 publications

(33 citation statements)

References 6 publications

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“…But the tendency still prevails and the magnetic shielding affect is smallest for the 90º angle between the current and ambient magnetic field. In more details this is discussed by Khazanov et al [2000Khazanov et al [ , 2001. Sanmartin and Estes [2002] proposed a similar model of magnetic shielding as Khazanov et al [2000Khazanov et al [ , 2001 with two changes.…”

Section: Discussionmentioning

confidence: 99%

“…The reason for such different role of magnetic shielding for these two orbits is discussed below. Results of this study are based on the model of magnetic shielding of Khazanov et al [2000Khazanov et al [ , 2001. Below we present the comparison of this model with the model of magnetic shielding developed by Sanmartin and Estes [2002].…”

Section: Discussionmentioning

confidence: 99%

“…It can be assumed that the plasma sheath and the boundary between the closed and open regions of magnetic field coincide, if their lengths are equal. Therefore, for that part of the tether where the length of the plasma sheath is larger than the length of the separatrix, the collected current can be calculated as OML current [Khazanov et al, 2000[Khazanov et al, , 2001. In the opposite case the current should be calculated from the thermal flux.…”

Section: Discussionmentioning

confidence: 99%

“…Different parameters describing tether performance, such as system acceleration and efficiency can be calculated, if the current distribution along the tether at the satellite trajectory is known. Below we present the results of current calculation along the expected trajectory of the MXER tether for wire and tape tethers with different cross-sections, and discuss the magnetic shielding effects based on the results of Khazanov et al [2001], Sanmartin and Estes [2002] papers, and the results of these calculations.…”

Section: Introductionmentioning

confidence: 99%

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Analyses of Bare-Tether Systems as a Thruster for MXER Studies

Khazanov¹,

Krivorutsky²,

Sorensen³

2005

41st AIAA/ASME/SAE/ASEE Joint Propulsion Conference &Amp;amp; Exhibit

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The concept of electrodynamic tether propulsion has a number of attractive features and has been widely discussed for different applications. A number of system designs have been proposed and compared during the last ten years. In spite of this, the choice of the proper design for a specific mission is far from evident. Such characteristics of tether performance as system acceleration, efficiency, etc. should be calculated and compared based on the known capability to collect electrical current. Different designs for the Momentum-eXchange/Electrodynamic Reboost (MXER) tether concept are presented, along with the necessary electrical potential and collected current levels. Corrections to the OML (Orbital Motion Limited) current due to the tether cross-section geometry and the magnetic field, produced by the tether current, are taken into account.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Analyses of Bare-Tether Systems as a Thruster for MXER Studies

Khazanov¹,

Krivorutsky²,

Sorensen³

2005

41st AIAA/ASME/SAE/ASEE Joint Propulsion Conference &Amp;amp; Exhibit

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“…The field due to the tether own current might reduce current collection. Strong redaction would roughly occur at tether points where some average radius r* of a magnetic separatrix modifying field topology in the cross-section plane exceeds the sheath radius r sh [15] …”

Section: Adiabatic Trapping and Other Bare-tether Issuesmentioning

confidence: 99%

A review of electrodynamic tethers for science applications

Sanmartin

2010

Plasma Sources Sci. Technol.

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Abstract. A bare electrodynamic tether (EDT) is a conductive thin wire or tape tens of kilometres long, which is kept taut in space by gravity gradient or spinning, and is left bare of insulation to collect (and carry) current as a cylindrical Langmuir probe in an ambient magnetized plasma. An EDT is a probe in mesothermal flow at highly positive (or negative) bias, with a large or extremely large 2D sheath, which may show effects from the magnetic self-field of its current and have electrons adiabatically trapped in its ram front. Beyond technical applications ranging from propellantless propulsion to power generation in orbit, EDTs allow broad scientific uses such as generating electron beams and artificial auroras; exciting Alfven waves and whistlers; modifying the radiation belts; and exploring interplanetary space and the Jovian magnetosphere. Asymptotic analysis, numerical simulations, laboratory tests, and planned missions on EDTs are reviewed.

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Magnetic self‐field effects on current collection by an ionospheric bare tether

Sanmartin

Estes

2002

J.‐Geophys.‐Res.

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[1] It was recently suggested that the magnetic field created by the current of a bare tether strongly reduces its own electron-collection capability when a magnetic separatrix disconnecting ambient magnetized plasma from tether extends beyond its electric sheath. It is here shown that current reduction by the self-field depends on the ratio L * /L t parameterizing bias and current profiles along the tether (L t tether length, L * characteristic length gauging ohmic effects) and on a new dimensionless number K s involving ambient and tether parameters. Current reduction is weaker the lower K s and L * / L t , which depend critically on the type of cross section: K s varies as R 5/3, h 2/3 R, and h 2/3 Â 1/4 width for wires, round tethers conductive only in a thin layer, and thin tapes, respectively; L * varies as R 2/3 for wires and as h 2/3 for tapes and round tethers conductive in a layer (R radius, h thickness). Self-field effects are fully negligible for the last two types of cross sections whatever the mode of operation. In practical efficient tether systems having L * /L t low, maximum current reduction in case of wires is again negligible for power generation; for deorbiting, reduction is <1% for a 10 km tether and $15% for a 20 km tether. In the reboost mode there are no effects for K s below some threshold; moderate effects may occur in practical but heavy reboost-wire systems that need no dedicated solar power.INDEX TERMS: 7807 Space Plasma Physics: Charged particle motion and acceleration; 7815 Space Plasma Physics: Electrostatic structures; 7853 Space Plasma Physics: Spacecraft/atmosphere interactions; 7855 Space Plasma Physics: Spacecraft sheaths, wakes, charging; KEYWORDS: ionospheric tethers, bare tethers, magnetic self-field of tethers, magnetic effects on current collection, orbital-motionlimited current, magnetic topology Citation: Sanmartin, J. R., and R. D. Estes, Magnetic self-field effects on current collection by an ionospheric bare tether,

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Current‐induced magnetic field effects on bare tether current collection: A parametric study

Cited by 11 publications

References 6 publications

Analyses of Bare-Tether Systems as a Thruster for MXER Studies

Analyses of Bare-Tether Systems as a Thruster for MXER Studies

A review of electrodynamic tethers for science applications

Magnetic self‐field effects on current collection by an ionospheric bare tether

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