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arxiv: 2107.11473 · v1 · pith:4XO7WUA4new · submitted 2021-07-23 · 🌌 astro-ph.IM · astro-ph.EP· gr-qc

A Mission to Nature's Telescope for High-Resolution Imaging of an Exoplanet

classification 🌌 astro-ph.IM astro-ph.EPgr-qc
keywords missionsolardesignsystemdistantpossiblecostever
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The solar gravitational lens (SGL) provides a factor of $10^{11}$ amplification for viewing distant point sources beyond our solar system. As such, it may be used for resolved imaging of extended sources, such as exoplanets, not possible otherwise. To use the SGL, a spacecraft carrying a modest telescope and a coronagraph must reach the SGLs focal region, that begins at $\sim$550 astronomical units (AU) from the Sun and is oriented outward along the line connecting the distant object and the Sun. No spacecraft has ever reached even a half of that distance; and to do so within a reasonable mission lifetime (e.g., less than 25 years) and affordable cost requires a new type of mission design, using solar sails and microsats ($<100$~kg). The payoff is high -- using the SGL is the only practical way we can ever get a high-resolution, multi-pixel image of an Earth-like exoplanet, one that we identify as potentially habitable. This paper describes a novel mission design starting with a rideshare launch from the Earth, spiraling in toward the Sun, and then flying around it to achieve solar system exit speeds of over $20$ AU/year. A new sailcraft design is used to make possible high area to mass ratio for the sailcraft. The mission design enables other fast solar system missions, starting with a proposed very low cost technology demonstration mission (TDM) to prove the functionality and operation of the microsat-solar sail design and then, building on the TDM, missions to explore distant regions of the solar system, and those to study Kuiper Belt objects (KBOs) and the recently discovered interstellar objects (ISOs) are also possible.

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Cited by 3 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Ultra-High-Resolution Astronomy with the Solar Gravitational Lens

    astro-ph.IM 2026-06 unverdicted novelty 6.0

    Presents an observability framework for solar gravitational lens astronomy and reports SSIM values of 0.993, 0.918, 0.973, and 0.923 for scalar reconstructions of four analytic scenes under stated assumptions.

  2. Propulsion Trades for a 2035-2040 Solar Gravitational Lens Mission

    astro-ph.EP 2026-02 unverdicted novelty 4.0

    To reach the solar gravitational lens at 650 AU in under 20 years requires solar sails with areal densities of 2-5 g/m² or nuclear electric propulsion with specific masses of 3-15 kg/kW_e depending on architecture.

  3. Propulsion Trades for a 2035-2040 Solar Gravitational Lens Mission

    astro-ph.EP 2026-02 unverdicted novelty 4.0

    Trade study of solar sail, NEP, and hybrid propulsion to achieve 154 km/s average speed for a 20-year trip to 650 AU.