Electric solar wind sail applications overview

AbstractWe analyse the potential of the electric solar wind sail for solar systemspace missions. Applications studied include y-by missions to terrestrialplanets (Venus, Mars and Phobos, Mercury) and asteroids, missions basedon non-Keplerian orbits (orbits that can be maintained only by applyingcontinuous propulsive force), one-way boosting to outer solar system, o -Lagrange point space weather forecasting and low-cost impactor probesfor added science value to other missions. We also discuss the generic ideaof data clippers (returning large volumes of high resolution scienti c datafrom distant targets packed in memory chips) and possible exploitation ofasteroid resources. Possible orbits were estimated by orbit calculations as-suming circular and coplanar orbits for planets. Some particular challengeareas requiring further research work and related to some more ambitiousmission scenarios are also identi ed and discussed. 1 Introduction The electric solar wind sail (E-sail) is an advanced concept for spacecraft propul-sion, based on momentum transfer from the solar wind plasma stream, inter-cepted by long and charged tethers [1]. The electrostatic eld created by thetethers deects trajectories of solar wind protons so that their ow-aligned mo-mentum component decreases. The ow-aligned momentum lost by the protonsis transferred to the charged tether by a Coulomb force (the charged tether ispulled by the plasma charge separation electric eld) and then transmitted tothe spacecraft as thrust. The concept is attractive for applications because nopropellant is needed for travelling over long distances. The E-sail’s operatingprinciple is di erent from other propellantless propulsion technologies such asthe solar photon sail [2] and the solar wind magnetic sail. The former is based1

[1]  Jean-Francois Roussel,et al.  Drifting Plasma Collection by a Positive Biased Tether Wire in LEO-Like Plasma Conditions: Current Measurement and Plasma Diagnostic , 2013, IEEE Transactions on Plasma Science.

[2]  Alessandro Antonio Quarta,et al.  Optimal Interplanetary Rendezvous Combining Electric Sail and High Thrust Propulsion System , 2011 .

[3]  Alessandro Antonio Quarta,et al.  Non-Keplerian orbits for electric sails , 2009 .

[4]  Pekka Janhunen,et al.  Simulation study of solar wind push on a charged wire: basis of solar wind electric sail propulsion , 2007 .

[5]  Alessandro Antonio Quarta,et al.  Electric Sail Missions to Potentially Hazardous Asteroids , 2010 .

[6]  James E. Polk,et al.  Feasibility of Capturing and Returning Small Near-Earth Asteroids , 2011 .

[7]  John E. Prussing,et al.  Solar Sailing: Technology, Dynamics, and Mission Applications , 2000 .

[8]  Pekka Janhunen,et al.  Electrostatic Plasma Brake for Deorbiting a Satellite , 2010 .

[9]  Patrice Couzin,et al.  Data Clippers: A new application for Solar sails and E-sails , 2010 .

[10]  Alessandro Antonio Quarta,et al.  Electric solar wind sail mass budget model , 2012 .

[11]  G. Saccoccia,et al.  Application of Solar Electric Propulsion for a Near-Sun, High-Inclination Mission , 2000 .

[12]  P. Janhunen,et al.  Increased electric sail thrust through removal of trapped shielding electrons by orbit chaotisation due to spacecraft body , 2009 .

[13]  Pekka Janhunen,et al.  Electric Sailing under Observed Solar Wind Conditions , 2009 .

[14]  Pekka Janhunen,et al.  Moving an asteroid with electric solar wind sail , 2010 .

[15]  P Salminen,et al.  Invited article: Electric solar wind sail: toward test missions. , 2010, The Review of scientific instruments.

[16]  R. Jedicke,et al.  The population of natural Earth satellites , 2011, 1112.3781.

[17]  H. Kratz,et al.  Electric solar wind sail : Toward test missions , 2010 .

[18]  Robert M. Zubrin,et al.  Magnetic sails and interplanetary travel , 1989 .