Solar Sails for Planetary Defense & High-Energy Missions

20 years after the successful ground deployment test of a (20 m)2 solar sail at DLR Cologne, and in the light of the upcoming U.S. NEAscout mission, we provide an overview of the progress made since in our mission and hardware design studies as well as the hardware built in the course of our solar sail technology development. We outline the most likely and most efficient routes to develop solar sails for useful missions in science and applications, based on our developed ‘now-term’ and near-term hardware as well as the many practical and managerial lessons learned from the DLR-ESTEC Gossamer Roadmap. Mission types directly applicable to planetary defense include single and Multiple NEA Rendezvous ((M)NR) for precursor, monitoring and follow-up scenarios as well as sail-propelled head-on retrograde kinetic impactors (RKI) for mitigation. Other mission types such as the Displaced L1 (DL1) space weather advance warning and monitoring or Solar Polar Orbiter (SPO) types demonstrate the capability of near-term solar sails to achieve asteroid rendezvous in any kind of orbit, from Earth-coorbital to extremely inclined and even retrograde orbits. Some of these mission types such as SPO, (M)NR and RKI include separable payloads. For one-way access to the asteroid surface, nanolanders like MASCOT are an ideal match for solar sails in micro-spacecraft format, i.e. in launch configurations compatible with ESPA and ASAP secondary payload platforms. Larger landers similar to the JAXA-DLR study of a Jupiter Trojan asteroid lander for the OKEANOS mission can shuttle from the sail to the asteroids visited and enable multiple NEA sample-return missions. The high impact velocities and re-try capability achieved by the RKI mission type on a final orbit identical to the target asteroid's but retrograde to its motion enables small spacecraft size impactors to carry sufficient kinetic energy for deflection.

[1]  Paul Zabel,et al.  ASTEROIDSQUADS/iSSB - A SYNERGETIC NEO DEFLECTION CAMPAIGN AND MITIGATION EFFECTS TEST MISSION SCENARIO , 2011 .

[2]  Line Drube,et al.  The NEOTωIST mission (Near-Earth Object Transfer of angular momentum spin test) , 2016 .

[3]  Thomas Sinn,et al.  ADEO PASSIVE DE-ORBIT SUBSYSTEM ACTIVITY LEADING TO A DRAGSAIL DEMONSTRATOR: CONCLUSION AND NEXT STEPS , 2017 .

[4]  D. Scheeres,et al.  Contact Motion on Surface of Asteroid , 2014 .

[5]  Keith DeWeese,et al.  Asteroid Redirect Mission Proximity Operations for Reference Target Asteroid 2008 EV5 , 2016 .

[6]  Matteo Ceriotti,et al.  Low-thrust to solar-sail trajectories: a homotopic approach , 2017 .

[7]  Daniel J. Scheeres,et al.  Solar Sail Orbit Operations at Asteroids: Exploring the Coupled Effect of an Imperfectly Reflecting Sail and a Nonspherical Asteroid , 2002 .

[8]  C. Pilorget,et al.  The MicrOmega Investigation Onboard Hayabusa2 , 2017 .

[9]  Martin A. Slade,et al.  Goldstone radar images of near-Earth asteroids (469896) 2007 WV4, 2014 JO25, 2017 BQ6, and 2017 CS , 2017 .

[10]  Michael Lange,et al.  MASCOT—The Mobile Asteroid Surface Scout Onboard the Hayabusa2 Mission , 2017 .

[11]  K. Glassmeier,et al.  The Rosetta Mission: Flying Towards the Origin of the Solar System , 2007 .

[12]  Jeffrey Hendrikse,et al.  On Time, On Target – How the Small Asteroid Lander MASCOT Caught a Ride Aboard HAYABUSA-2 in 3 Years, 1 Week and 48 Hours , 2015 .

[13]  P. Michel,et al.  Asteroid Impact and Deflection Assessment mission , 2015 .

[14]  Chris Becker,et al.  Solar Sail Attitude Control System for the NASA Near Earth Asteroid Scout Mission , 2017 .

[15]  Sergio Montenegro,et al.  Instrumentation for an asteroid kinetic-impactor demonstration mission , 2016 .

[16]  Wolfgang Seboldt,et al.  Ground-Based Demonstration of Solar Sail Technology , 2000 .

[17]  Christian Grimm,et al.  DLR MASCOT on HAYABUSA-II, A Mission That May Change Your Idea of Life: AIV Challenges in a Fast Paced and High Performance Deep Space Project , 2013 .

[18]  Stephan Ulamec,et al.  One Shot to an Asteroid- MASCOT and the Design of an Exclusively Primary Battery Powered Small Spacecraft in Hardware Design Examples and Operations Considerations , 2014 .

[19]  Andy Braukhane,et al.  Statistics and Evaluation of 30+ Concurrent Engineering Studies at DLR , 2012 .

[20]  Vincent Hamm,et al.  Calibration of MicrOmega Hayabusa-2 Flight Model — First Results , 2016 .

[21]  Peter Lebedew,et al.  Untersuchungen über die Druckkräfte des Lichtes , 1901 .

[22]  M. Rayman The successful conclusion of the Deep Space 1 Mission: important results without a flashy title , 2002 .

[23]  Hiroki Senshu,et al.  Asteroid Ryugu before the Hayabusa2 encounter , 2018, Progress in Earth and Planetary Science.

[24]  Daniel J. Scheeres,et al.  Radar Imaging of Binary Near-Earth Asteroid (66391) 1999 KW4 , 2006, Science.

[25]  Volker Maiwald Initial Results of a New Method for Optimizing Low-Thrust Gravity-Assist Missions , 2017 .

[26]  Isao Kawano,et al.  In-orbit Demonstration of an Unmanned Automatic Rendezvous and Docking System by the Japanese Engineering Test Satellite ETS-VII , 1994 .

[27]  Bernd Dachwald,et al.  LARGE LIGHTWEIGHT DEPLOYABLE STRUCTURES FOR PLANETARY DEFENCE: SOLAR SAIL PROPULSION, SOLAR CONCENTRATOR PAYLOADS, LARGE-SCALE PHOTOVOLTAIC POWER , 2015 .

[28]  Colin R. McInnes,et al.  Gossamer Roadmap Technology Reference Study for a Solar Polar Mission , 2014 .

[29]  Bernd Dachwald,et al.  Capabilities of Gossamer-1 derived small spacecraft solar sails carrying Mascot-derived nanolanders for in-situ surveying of NEAs , 2019, Acta Astronautica.

[30]  Franz Lura,et al.  The 3-step DLR–ESA Gossamer road to solar sailing , 2011 .

[31]  Michael Lange,et al.  Experimental Determination of the Structural Coefficient of Restitution of a Bouncing Asteroid Lander , 2017 .

[32]  Hajime Yano,et al.  A Small Asteroid Lander Mission to Accompany Hayabusa-II , 2012 .

[33]  Stephan Ulamec,et al.  Mobile Asteroid Surface Scout (MASCOT) - Design, Development and Delivery of a Small Asteroid Lander Aboard Hayabusa2 , 2015 .

[34]  S. Montenegro,et al.  The Ends of Small – Practical Engineering Constraints in the Design of Planetary Defence Missions , 2013 .

[35]  Olive R. Stohlman,et al.  Temperature-Driven Shape Changes of the Near Earth Asteroid Scout Solar Sail , 2017 .

[36]  Junichiro Kawaguchi,et al.  Design of a Lander for In-Situ Investigation and Sample-Return from a Jupiter Trojan Asteroid on the Solar Power Sail Mission , 2015 .

[37]  C. Pilorget,et al.  NIR reflectance hyperspectral microscopy for planetary science: Application to the MicrOmega instrument , 2013 .

[38]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[39]  W. Seboldt,et al.  ENEAS - Exploration of Near-Earth Asteroids with a Sailcraft - Proposal for a Small Satellite Mission with the Space Science Program of Germany , 2000 .

[40]  Christian Grimm,et al.  From idea to flight - A review of the Mobile Asteroid Surface Scout (MASCOT) development and a comparison to historical fast-paced space programs , 2019, Progress in Aerospace Sciences.

[41]  K. Schilling,et al.  Resource sharing , communication and control for fractionated spacecraft ( YETE ) , 2015 .

[42]  Jens Biele,et al.  Thermophysical modeling of Didymos’ moon for the Asteroid Impact Mission , 2017 .

[43]  Simon F. Green,et al.  Asteroid belt multiple flyby options for M-Class Missions , 2016 .

[44]  P. Cochat,et al.  Et al , 2008, Archives de pediatrie : organe officiel de la Societe francaise de pediatrie.

[45]  Bernd Dachwald,et al.  From Sail to Soil - Getting Sailcraft out of the Harbour on a Visit to One of Earth's Nearest Neighbours , 2015 .

[46]  Martin E. Zander,et al.  Gossamer-1: Mission concept and technology for a controlled deployment of gossamer spacecraft , 2017 .

[47]  P. Kidwell Journey to the moon: the history of the Apollo guidance computer , 1999, IEEE Annals of the History of Computing.

[48]  Christian Grimm,et al.  Going Beyond the Possible, Going Beyond the “Standard” of Spacecraft Integration and Testing! , 2015 .

[49]  Bernd Dachwald,et al.  Multiple near-Earth asteroid rendezvous and sample return using first generation solar sailcraft , 2005 .

[50]  Thomas Renger,et al.  The Complex Irradiation Facility at DLR-Bremen , 2014 .

[51]  Naeem Ahmad,et al.  Near Earth Asteroid Scout Solar Sail Thrust and Torque Model , 2017 .

[52]  E. F. Nichols,et al.  The Pressure Due To Radiation , 2015 .

[53]  I Pelivan Thermophysical modelling for high-resolution digital terrain models , 2018 .

[54]  Matteo Ceriotti,et al.  From Low Thrust to Solar Sailing: A Homotopic Approach , 2016 .

[55]  Alain Herique,et al.  A Direct Observation of the Asteroid's Structure from Deep Interior to Regolith: Two Radars on the AIM Mission , 2016 .

[56]  Patric Seefeldt,et al.  A stowing and deployment strategy for large membrane space systems on the example of Gossamer-1 , 2017 .

[57]  Wolfgang Seboldt,et al.  Solar sail technology development and demonstration , 2003 .

[58]  Volker Maiwald ABOUT COMBINING TISSERAND GRAPH GRAVITY-ASSIST SEQUENCING WITH LOW-THRUST TRAJECTORY OPTIMIZATION , 2016 .

[59]  Christian Grimm,et al.  Nanoscale landers and instrument carriers: enhancing larger mission's science return by investing in low cost solutions: the MASCOT‐1 to X and ROBEX examples , 2015 .

[60]  Maciej Sznajder,et al.  Degradation of metallic surfaces under space conditions, with particular emphasis on Hydrogen recombination processes , 2015, 1506.01790.

[61]  Volker Maiwald A new method for optimization of low-thrust gravity-assist sequences , 2017 .

[62]  Bernd Dachwald,et al.  Gossamer Roadmap Technology Reference Study for a Multiple NEO Rendezvous Mission , 2014 .

[63]  Matteo Ceriotti,et al.  Multiple near-earth asteroid rendezvous mission: Solar-sailing options , 2017 .

[64]  Vishnu Reddy,et al.  Detection of water and/or hydroxyl on asteroid (16) Psyche , 2016 .

[65]  N. Meyer‐Vernet,et al.  Basics of the Solar Wind , 2007 .

[66]  Daniel J. Scheeres,et al.  Radar observations and the shape of near-Earth asteroid 2008 EV5 , 2011, 1101.3794.

[67]  Jerry E. Warren,et al.  An Advanced Composites-Based Solar Sail System for Interplanetary Small Satellite Missions , 2018 .

[68]  M. Leipold,et al.  A Summary of Solar Sail Technology Developments and Proposed Demonstration Missions , 1999 .

[69]  Jan Thimo Grundmann,et al.  Membrane Deployment Technology Development at DLR for Solar Sails and Large-Scale Photovoltaics , 2019, 2019 IEEE Aerospace Conference.

[71]  A. Thirouin,et al.  THE FAST SPIN OF NEAR-EARTH ASTEROID ( 455213 ) 2001 OE 84 , REVISITED AFTER 14 YEARS – ARGUMENTS FOR A HIGHLY COHESIVE INTERNAL STRUCTURE , 2017 .

[72]  Colin R. McInnes,et al.  Deflection of near-Earth asteroids by kinetic energy impacts from retrograde orbits , 2004 .

[73]  D. Plettemeier,et al.  Direct observations of asteroid interior and regolith structure: Science measurement requirements , 2017, Advances in Space Research.

[74]  Bernd Dachwald,et al.  Gossamer Roadmap Technology Reference Study for a Sub-L1 Space Weather Mission , 2014 .

[75]  John C. Mankins,et al.  Technology Readiness Levels-A White Paper , 1995 .

[76]  Charles H. Acton,et al.  Asteroid 5535 Annefrank size, shape, and orientation: Stardust first results , 2004 .

[77]  Richard P. Binzel,et al.  The New Horizons Distant Flyby of Asteroid 2002 JF56 , 2006 .

[78]  Kaname Sasaki,et al.  Controlled Deployment of Gossamer Spacecraft , 2017 .

[79]  Tsuyoshi Murata,et al.  {m , 1934, ACML.

[80]  H. Müller,et al.  Implementation of concurrent engineering to Phase B space system design , 2011 .

[81]  Elizabeth Mabrouk What are SmallSats and CubeSats , 2015 .

[82]  Michael Lange,et al.  MASCOT - Structures design and qualification of an "organic" mobile pander platform for low gravity bodies , 2014 .

[83]  Akira Fujiwara,et al.  Hayabusa—Its technology and science accomplishment summary and Hayabusa-2 , 2006 .

[84]  Frank Dannemann,et al.  Wireless Avionics for a Solar Sailer (GOSSAMER-1) , 2012 .

[85]  Line Drube,et al.  HOW TO FIND METAL-RICH ASTEROIDS , 2014, 1403.6346.

[86]  Alessandro Peloni Solar-sail mission design for multiple near-Earth asteroid rendezvous , 2018 .

[87]  W. Blume,et al.  Deep Impact – A Review of the World's Pioneering Hypervelocity Impact Mission , 2015 .

[88]  Bernd Dachwald,et al.  Soil to Sail - Asteroid Landers on Near-Term Sailcraft as an Evolution of the Gossamer Small Spacecraft Solar Sail Concept for In-Situ Characterization , 2017 .

[89]  P. E. Beyer,et al.  Galileo early cruise, including Venus, First Earth, and Gaspra encounters , 1992 .

[90]  Mattia Pugliatti,et al.  NEOTωIST - An Asteroid Impactor Mission Featuring Sub-spacecraft for Enhanced Mission Capability , 2016 .

[91]  Hartmut Müller,et al.  A space-based mission to characterize the IEO population , 2013 .

[92]  Siebo Reershemius,et al.  HP3 Instrument Support System Structure Development for the NASA/JPL Mars Mission InSight , 2019, 2019 IEEE Aerospace Conference.

[93]  Colin R. McInnes,et al.  GeoSail: an elegant solar sail demonstration mission , 2007 .

[94]  Homer D. Hagstrum,et al.  Theory of Auger Ejection of Electrons from Metals by Ions , 1954 .

[95]  Thomas Renger,et al.  Small Spacecraft Solar Sailing for Small Solar System Body Multiple Rendezvous and Landing , 2018 .

[96]  Patric Seefeldt,et al.  Qualification Testing of the Gossamer-1 Deployment Technology , 2016 .

[97]  P ? ? ? ? ? ? ? % ? ? ? ? , 1991 .

[98]  Rita Schulz,et al.  Rosetta fly-by at asteroid (21) Lutetia: An overview , 2012 .

[99]  Tobias Mikschl,et al.  YETE: Distributed, Networked Embedded Control Approaches for Efficient, Reliable Mobile Systems , 2014 .

[100]  J. Maxwell A Treatise on Electricity and Magnetism , 1873, Nature.

[101]  Bernd Dachwald,et al.  Head-On Impact Deflection of NEAs: A Case Study for 99942 Apophis , 2007 .

[102]  Les Johnson,et al.  Near Earth Asteroid (NEA) Scout , 2014 .

[103]  Simon Tardivel,et al.  The Deployment of Scientific Packages to Asteroid Surfaces , 2014 .

[104]  Robert Axmann,et al.  TET-1 SATELLITE OPERATIONS LESSONS LEARNED: PREPARATION OF MISSION, LEOP ANDROUTINE OPERATIONS OF 11 DIFFERENT EXPERIMENTS , 2011 .

[105]  Anil V. Rao,et al.  Automated Trajectory Optimizer for Solar Sailing (ATOSS) , 2018 .

[106]  S. B. Die Rakete zu den Planetenräumen , 1924, Nature.

[107]  Joachim M. Blum,et al.  Science case for the Asteroid Impact Mission (AIM): A component of the Asteroid Impact & Deflection Assessment (AIDA) mission , 2016 .

[108]  Eric P. Wenaas,et al.  Theory of Auger ejection of electrons from metals by ions , 1969 .

[109]  Juan M. Fernandez,et al.  Advanced Deployable Shell-Based Composite Booms for Small Satellite Structural Applications Including Solar Sails , 2017 .

[110]  Joseph A. Burns,et al.  Saturn's Mysterious Arc-Embedded Moons: Recycled Fluff? , 2013 .

[111]  Steven R. Oleson,et al.  Advanced solar cell and array technology for NASA deep space missions , 2008, 2008 33rd IEEE Photovoltaic Specialists Conference.

[112]  Takanao SAIKI,et al.  Direct Exploration of Jupiter Trojan Asteroid using Solar Power Sail 1 , 2016 .

[113]  Volker Maiwald APPLICABILITY OF TISSERAND CRITERION FOR OPTIMIZATION OF GRAVITY-ASSIST SEQUENCES FOR LOW-THRUST MISSIONS , 2015 .

[114]  Andrew Ging Regaining 20 Watts for the Cassini Power System , 2010 .

[115]  Federico Cordero MASCOT Lander Operational Concept and its Autonomy, General Services and Resource Optimisation Implementation in the On-Board Software , 2016 .

[116]  W. Keats Wilkie,et al.  NASA's Advanced Solar Sail Propulsion System for Low-Cost Deep Space Exploration and Science Missions that Use High Performance Rollable Composite Booms , 2017 .

[117]  Denis Estublier,et al.  Smart-1: An analysis of flight data , 2005 .

[118]  M. Leipold,et al.  ODISSEE - A Proposal for Demonstration of a Solar Sail in Earth Orbit , 1999 .

[119]  Hitoshi Kuninaka,et al.  Flight status of robotic asteroid sample return mission Hayabusa2 , 2016 .