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3 Pith papers cite this work. Polarity classification is still indexing.

3 Pith papers citing it

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astro-ph.EP 3

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2026 3

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UNVERDICTED 3

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representative citing papers

Oxidation Constraints on Terrestrial Planet Formation from a Ring

astro-ph.EP · 2026-05-29 · unverdicted · novelty 6.0

Narrow-ring accretion models for terrestrial planets cannot reproduce bulk silicate Earth composition because embryos mix reduced and oxidized planetesimals early, requiring segregated reservoirs and late oxidized delivery.

Modeling carbon outgassing from chondritic planetesimals

astro-ph.EP · 2026-05-28 · unverdicted · novelty 5.0

Numerical model of C outgassing shows CC planetesimals deplete >50% carbon while NCs deplete <50% for typical sizes and formation times, favoring NC bodies as the main C source for terrestrial planets.

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Showing 3 of 3 citing papers after filters.

  • Thermal and rotational effects of giant impacts during terrestrial planet accretion astro-ph.EP · 2026-06-22 · unverdicted · none · ref 75

    Hydrodynamical simulations of giant impacts find lower post-impact CMB pressures due to thermal and rotational effects, common full mantle melting, and conditions favoring metal-silicate equilibration near the CMB.

  • Oxidation Constraints on Terrestrial Planet Formation from a Ring astro-ph.EP · 2026-05-29 · unverdicted · none · ref 37

    Narrow-ring accretion models for terrestrial planets cannot reproduce bulk silicate Earth composition because embryos mix reduced and oxidized planetesimals early, requiring segregated reservoirs and late oxidized delivery.

  • Modeling carbon outgassing from chondritic planetesimals astro-ph.EP · 2026-05-28 · unverdicted · none · ref 88

    Numerical model of C outgassing shows CC planetesimals deplete >50% carbon while NCs deplete <50% for typical sizes and formation times, favoring NC bodies as the main C source for terrestrial planets.