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| Format: | Preprint |
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2026
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| Online Access: | https://arxiv.org/abs/2605.22682 |
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| _version_ | 1866918516670595072 |
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| author | Gabryszewski, Ryszard Czechowski, Leszek Hess, Arkadiusz |
| author_facet | Gabryszewski, Ryszard Czechowski, Leszek Hess, Arkadiusz |
| contents | We assess the dynamical feasibility of redirecting small volatile-bearing trans-Neptunian objects (TNOs) onto Mars-impacting orbits using continuous low-thrust propulsion and a single gravity-assist encounter. The study considers two representative dynamical classes: classical Kuiper Belt--like and Scattered Disk--like initial orbits, and determines the minimum characteristic velocity increment $ΔV$ required to drive the objects onto a Mars-impacting trajectory within a specified transfer time $ΔT$. The dynamics is modelled in the two-body problem with a fixed maximum low thrust included, allowing the computed $ΔV$ to represent a dynamical lower bound independent of specific propulsion-technical implementation.
Three trajectory classes are investigated: (i) inward spiral transfer, (ii) time-dependent thrust-direction steering optimized via global evolutionary algorithms, and (iii) hybrid transfers combining low thrust with a single Neptune flyby. Pure spiral trajectories yield very high velocity expenditures ($ΔV \gtrsim 22~\mathrm{km~s^{-1}}$) and millennia durations, confirming that monotonic inward migration is dynamically inefficient for TNO redirection. In contrast, optimized steering strategies systematically increase orbital eccentricity and achieve Mars-impacting geometries with $ΔV \approx 2.5$--$3.2~\mathrm{km~s^{-1}}$ over 380--540 yr timescales. A single Neptune encounter further reduces the total $ΔV$ in favourable cases, with minimum values falling below those of direct optimized transfers. These results establish a quantitative lower bound on the energy cost of importing volatiles from the outer Solar System to Mars, showing that controlled redirection is feasible under modest $ΔV$ budgets when target bodies are chosen from favourable regions of orbital phase space. |
| format | Preprint |
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arxiv_https___arxiv_org_abs_2605_22682 |
| institution | arXiv |
| publishDate | 2026 |
| record_format | arxiv |
| spellingShingle | Energetic Feasibility of Redirecting Trans-Neptunian Objects onto Mars-Impacting Orbits: Continuous Thrust and Gravity Assist Trajectories Gabryszewski, Ryszard Czechowski, Leszek Hess, Arkadiusz Earth and Planetary Astrophysics We assess the dynamical feasibility of redirecting small volatile-bearing trans-Neptunian objects (TNOs) onto Mars-impacting orbits using continuous low-thrust propulsion and a single gravity-assist encounter. The study considers two representative dynamical classes: classical Kuiper Belt--like and Scattered Disk--like initial orbits, and determines the minimum characteristic velocity increment $ΔV$ required to drive the objects onto a Mars-impacting trajectory within a specified transfer time $ΔT$. The dynamics is modelled in the two-body problem with a fixed maximum low thrust included, allowing the computed $ΔV$ to represent a dynamical lower bound independent of specific propulsion-technical implementation. Three trajectory classes are investigated: (i) inward spiral transfer, (ii) time-dependent thrust-direction steering optimized via global evolutionary algorithms, and (iii) hybrid transfers combining low thrust with a single Neptune flyby. Pure spiral trajectories yield very high velocity expenditures ($ΔV \gtrsim 22~\mathrm{km~s^{-1}}$) and millennia durations, confirming that monotonic inward migration is dynamically inefficient for TNO redirection. In contrast, optimized steering strategies systematically increase orbital eccentricity and achieve Mars-impacting geometries with $ΔV \approx 2.5$--$3.2~\mathrm{km~s^{-1}}$ over 380--540 yr timescales. A single Neptune encounter further reduces the total $ΔV$ in favourable cases, with minimum values falling below those of direct optimized transfers. These results establish a quantitative lower bound on the energy cost of importing volatiles from the outer Solar System to Mars, showing that controlled redirection is feasible under modest $ΔV$ budgets when target bodies are chosen from favourable regions of orbital phase space. |
| title | Energetic Feasibility of Redirecting Trans-Neptunian Objects onto Mars-Impacting Orbits: Continuous Thrust and Gravity Assist Trajectories |
| topic | Earth and Planetary Astrophysics |
| url | https://arxiv.org/abs/2605.22682 |