TY - GEN
T1 - Deflection of earth-crossing asteroids/comets using rendezvous spacecraft and laser ablation
AU - Park, Sang Young
AU - Mazanek, Daniel D.
PY - 2004
Y1 - 2004
N2 - Space missions are presented to deflect four fictitious Earth impacting objects by using an advanced magnetoplasma spacecraft designed to deliver a laser ablation payload. The laser energy required to provide sufficient change in velocity is estimated for one long-period comet and three asteroids, and an optimal rendezvous trajectory is provided for each threat scenario. The end-to-end simulations provide an overall concept for solving the deflection problem. These analyses illustrate that the optimal deflection strategy is highly dependent on the size and the orbital elements of the impacting object, as well as the amount of warning time. A rendezvous spacecraft with a multi-megawatt laser ablation payload could be available by the year 2050. This approach could provide a capable and robust orbit modification approach for altering the orbits of Earth-crossing objects with relatively small size or long warning time. Significant technological advances, multiple spacecraft, or alternative deflection techniques are required for a feasible scenario to protect the Earth from an impacting celestial body with large size and short warning time.
AB - Space missions are presented to deflect four fictitious Earth impacting objects by using an advanced magnetoplasma spacecraft designed to deliver a laser ablation payload. The laser energy required to provide sufficient change in velocity is estimated for one long-period comet and three asteroids, and an optimal rendezvous trajectory is provided for each threat scenario. The end-to-end simulations provide an overall concept for solving the deflection problem. These analyses illustrate that the optimal deflection strategy is highly dependent on the size and the orbital elements of the impacting object, as well as the amount of warning time. A rendezvous spacecraft with a multi-megawatt laser ablation payload could be available by the year 2050. This approach could provide a capable and robust orbit modification approach for altering the orbits of Earth-crossing objects with relatively small size or long warning time. Significant technological advances, multiple spacecraft, or alternative deflection techniques are required for a feasible scenario to protect the Earth from an impacting celestial body with large size and short warning time.
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U2 - 10.2514/6.2004-1433
DO - 10.2514/6.2004-1433
M3 - Conference contribution
AN - SCOPUS:20344381336
SN - 1563477114
SN - 9781563477119
T3 - Collection of Technical Papers - 2004 Planetary Defense Conference: Protecting Earth from Asteroids
SP - 257
EP - 268
BT - Collection of Technical Papers - 2004 Planetary Defense Conference
PB - American Institute of Aeronautics and Astronautics Inc.
T2 - Collection of Technical Papers - 2004 Planetary Defense Conference: Protecting Earth from Asteroids
Y2 - 23 February 2004 through 26 February 2004
ER -