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Near-Earth objects – a threat for Earth? Or: NEOs for engineers and physicists

Near-Earth objects – a threat for Earth? Or: NEOs for engineers and physicists Lecture 8 – Deflection missions in detail Prof. Dr. E. Igenbergs (LRT) Dr. D. Koschny (ESA). Image credit: ESA. News. Workshop on 2011 AG5 took place at Goddard Space Flight Center on 29 May 2012

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Near-Earth objects – a threat for Earth? Or: NEOs for engineers and physicists

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  1. Near-Earth objects – a threat for Earth? Or: NEOs for engineers and physicists Lecture 8 – Deflection missions in detail Prof. Dr. E. Igenbergs (LRT) Dr. D. Koschny (ESA) Image credit: ESA

  2. News • Workshop on 2011 AG5 took place at Goddard Space Flight Center on 29 May 2012 • 2011 AG5 is highest on risk list – 1:500. But: low confidence • No need to act now. Observations in 2013 will be timely enough • A 2nd preparation meeting for the ‘Space Mission Planning and Advisory Group (SMPAG)’ took place in Vienna, last Friday • 15 participants from international space agencies (ESA, NASA, JAXA, China, Russia, Iran, Switzerland, CNES, Romania…) • Discussed ‘Terms of Reference’ for the SMPAG • “Action Team 14” discussions on how to set up a global impact response network took place Monday/Tuesday 11/12 June 2012

  3. Context Mitigation preparation 3

  4. Outline • How far do we need to deflect? • Overview of possible deflection missions • In detail: The Ion-Beam Shepherd • In detail: The kinetic impactor (if time)

  5. The b-plane • The ‘b-plane’ (body plane) is the plane going through the center of the Earth and perpendicular to the incoming velocity vector of the asteroid outside the sphere of influence

  6. Apophis flyby geometry

  7. Apophis b-plane

  8. Keyholes for Apophis D. Bancelin (2011)

  9. Keyholes for Apophis in the b-plane D. Bancelin (2011)

  10. Deflection success • Asteroid does not hit Earth (miss distance is n * Rearth where n is still tbd) • Asteroid does not go through a keyhole Head-On Impact Deflection of NEAs: A Case Study for 99942 Apophis, Planetary Defense Conference 2007, 05-08 Mar 2007, Wash. DC. See http://www.doom2036.com/P2-3--Dachwald.pdf

  11. Overview of deflection concepts • “Impulsive” techniques • Kinetic impactor • Nuclear (stand-off) explosion • “Slow-push” (or –pull) techniques • Gravity tractor • Ion-beam shepherd • Mass driver • Albedo change • Mirror-bee concept • Solar shadow • Electric solar wind sail

  12. Impulsive techniques – Don Quijote • Movie at http://www.youtube.com/watch?v=h0FTByUifR4 • ESA-funded study performed around 2004 by European industry • Orbiter and impactor (Hidalgo and Sancho)

  13. Impulsive techniques – AIDA • ESA-internal study performed in 2012 with APL/USA • Impacting the smaller object of a binary asteroid • Orbital period will change • Can be seen in light curves • => Easier to measure! NEA binary 1999 KW4 - Radar derived shape model of the NEA binary 1999 KW4 (Ostro et al., 2006). Pravec et al. (2006)

  14. Impulsive techniques – Nuclear • “Stand-off” explosion • Radiation pressure of x-ray photons and thermal vaporisation produce push • Politically sensitive • Studied by TSNIIMASH within the EC-funded NEOShield project (http://new.tsniimash.ru/) • Studied by some US-based groups (e.g. Los Alamos) Yield of Hiroshima bomb: 15 kt TNT (1 kt TNT = 4.2 1012 J)

  15. Impulsive techniques – The big issue • Effectiveness of momentum transfer is a BIG unknown! • b is the momentum transfer efficiency • b ranges from 0 to 20 (?) • Change in position can be estimated from the following formula (Ahrens and Harris 1994):

  16. Some typical numbers: • Deep Impact mission: 370 kg impactor10.2 km/s => target comet about 8 x 5 x 5 km3 • Deflection after half an orbit about 6 m (as computed in Workshop #03)

  17. Slow-push/pull techniques • Gravity tractor

  18. Slow-push/pull techniques • Ion-beam shepherd

  19. Slow-push/pull techniques • Mass driver

  20. Slow-push/pull techniques • Mirror-bee

  21. Slow-push/pull techniques • Solar shadowing

  22. Slow-push/pull techniques • Albedo change http://aeweb.tamu.edu/aemp/index.php?page=albedo

  23. Slow-push/pull techniques • Electric solar wind sail (http://spacegeneration.org/images/stories/Projects/NEO/Sini_Merikallio.pdf)

  24. Slow-push/pull techniques • The ultimate solution?

  25. Slow-push/pull techniques • The ultimate solution? • No… see “The graveyard of Alderaan”

  26. Overview of deflection conceptsand my assessment • “Impulsive” techniques • Kinetic impactor – feasible – Guidance issues? • Nuclear (stand-off) explosion – political issues • “Slow-push” (or –pull) techniques • Gravity tractor – feasible but difficult • Ion-beam shepherd – feasible and interesting • Mass driver – science fiction • Albedo change – science fiction • Mirror-bee concept – science fiction • Solar shadow – size of sail? Not quite sci fi? • Electric solar wind sail – how to attach? Sci fi

  27. In more detail • Ion Beam Shepherd for Asteroid Deflection • C. Bombardelli, J. Pelaez, arXiv:1102.1276v1 [physics.space-ph] (2011)

  28. In more detail • GT = Gravity tractor • IBS1 = ‘near-future’ ion thruster • IBS2 = ‘state of the art’ thruster • From: C. Bombardelli, J. Pelaez, arXiv:1102.1276v1 [physics.space-ph] (2011)

  29. Summary • Overview of deflection mission strategies from a technical point of view • We learned how to demonstrate a kinetic impactor mission such that the effect could actually be measured • We learned some details on the so-called Ion-Beam Shephard (IBS) • In workshop: • Look at impactor on secondary in 1999 FG3 – how much will the orbital period be changed • Is the IBS is feasible?

  30. Workshop – task 1 • Take the binary asteroid 1996FG3. The distance between the two components is 2.8 km. Assume a circular orbit. What is the orbital period? Assume an asteroid density of1.4 g/cm3and a momentum efficiency of b = 2. • Assume that the Deep Impact impactor hits the secondary (370 kg, 10.2 km/s). By how much do you change the period? How can this be measured?

  31. Workshop – task 1 - Hint Assume circular orbit – compute velocity ‘before’ from observed period Compute new velocity using conversation of momentum Assume same orbit, compute new period with new velocity. What’s the difference in seconds? To assess whether it is measureable: How many periods are there in one year? What is the accumulated change in period over a year? What does this mean for any observed eclipses between the two objects?

  32. Workshop – task 1 - Hint Alternatively: Use the vis-viva theorem to compute the new semi-major axis; then use Kepler’s 3rd law to compute the change in the period.

  33. Workshop – task 1 - Hint Alternatively: Use the vis-viva theorem to compute the new semi-major axis; then use Kepler’s 3rd law to compute the change in the period.

  34. Workshop – task 2 – Ion-Beam Shepherd Image credits: ESA (*) http://www.snecma.com/IMG/files/fiche_pps1350g_ang_2011_modulvoir_file_fr.pdf Let’s assume that we want to use two Smart-1 spacecraft mounted ‘back-to-back’ as Ion-Beam Shepherd. Using the data sheet of the S-1 ion engine (*), where would you put the spacecraft? How much do you shift Apophis after one year/two years/ten years/twenty years?

  35. Workshop – task 2 – Hint (*) http://www.snecma.com/IMG/files/fiche_pps1350g_ang_2011_modulvoir_file_fr.pdf • Assume a distance to the asteroid such that the complete ion beam will impinge the asteroid • The thrust of the engine is given (in Newton) • From that, compute s = f (t)

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