On the practical exploitation of perturbative effects in low Earth orbit for space debris mitigation

Abstract This paper presents the results of a numerical evaluation of the natural lifetime reduction in low Earth orbit, due to dynamical perturbations. The study considers two values for the area-to-mass ratio, a nominal ratio which resembles a typical value of spacecraft in orbit today, and an enhanced ratio which covers the surface augmentation. The results were obtained with two orbit propagators, one of a semi-analytical nature and the second one using non-averaged equations of motion. The simulations for both propagators were set up similarly to allow comparison. They both use the solar radiation pressure and the secular terms of the geopotential ( J 2 , J 4 and J 6 ). The atmospheric drag was turned on and off in both propagators to alternatively study the eccentricity build up and the residual lifetime. The non-averaging case also covers a validation with the full 6 × 6 geopotential. The results confirm the findings in previous publications, that is, the possibility for de-orbiting from altitudes above the residual atmosphere if a solar sail is deployed at the end-of-life, due to the combined effect of solar radiation pressure and the oblateness of the Earth. At near polar inclinations, shadowing effects can be exploited to the same end. The results obtained with the full, non-averaging propagator revealed additional de-orbiting corridors associated with solar radiation pressure which were not found by previous work on space debris mitigation. The results of both tools are compared for specific initial conditions. For nominal values of area-to-mass ratio, instead, it is confirmed that this resonance effect is negligible. The paper then puts the findings in the perspective of the current satellite catalogue. It identifies space missions which are currently close to a resonance corridor and shows the orbit evolution within the resonances with a significantly shorter residual orbital lifetime. The paper finishes with a discussion on the exploitation of these effects with regards to the long-term simulation of the space debris environment and a flux and collision probability comparison.

[1]  G. E. Cook Luni-Solar Perturbations of the Orbit of an Earth Satellite , 1961 .

[2]  Alessandro Rossi,et al.  Exploiting dynamical perturbations for the end-of-life disposal of spacecraft in LEO , 2018, Astronomy and Computing.

[3]  G. B. Valsecchi,et al.  Solar radiation pressure resonances in Low Earth Orbits , 2017, 1709.09895.

[4]  Alessandro Rossi,et al.  ReDSHIFT: A Global Approach to Space Debris Mitigation , 2018, Aerospace.

[5]  D. Vallado Fundamentals of Astrodynamics and Applications , 1997 .

[6]  Camilla Colombo,et al.  A passive satellite deorbiting strategy for medium earth orbit using solar radiation pressure and the J 2 effect , 2012 .

[7]  B. B. Virgili,et al.  Drag and Solar Sail Deorbiting: Re-Entry Time Versus Cumulative Collision Probability , 2017 .

[8]  Massimiliano Vasile,et al.  Effectiveness of GNSS disposal strategies , 2014 .

[9]  Alessandro Rossi,et al.  Natural highways for end-of-life solutions in the LEO region , 2018, 1805.05726.

[10]  H. Klinkrad Space Debris: Models and Risk Analysis , 2006 .

[11]  I I Shapiro,et al.  Effects of Solar Radiation Pressure on Earth Satellite Orbits , 1960, Science.

[12]  John F. Moxnes,et al.  Projected area and drag coefficient of high velocity irregular fragments that rotate or tumble , 2017 .

[13]  Peter Musen,et al.  The Influence of the Solar Radiation Pressure on the Motion of an Artificial Satellite , 1960 .

[14]  Massimiliano Vasile,et al.  End-of-life disposal concepts for libration point orbit and highly elliptical orbit missions , 2015 .

[15]  E. Opik,et al.  COLLISION PROBABILITIES WITH THE PLANETS AND THE DISTRIBUTION OF INTERPLANETARY MATTER , 2016 .