Crater Distributions of Uranus's Mid-sized Satellites and Implications for Outer Solar System Bombardment

Kirchoff, M. R.; Dones, L.; Singer, K. N.; Schenk, P.

doi:10.3847/psj/ac42d7

Cited by 28 publications

(74 citation statements)

References 79 publications

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“…Ariel's surface can be separated into four broad geologic units: ancient, cratered plains that represent the oldest terrain on Ariel and are thought to be 1.3 (−0.6/+2.0) Ga (Kirchoff et al 2022), and three younger, "smooth materials" units that are subdivided based on their relative ages (Smith et al 1986;Jankowski & Squyres 1988; see Figure 2). The Pixie Group is mostly found within the "intermediate-age smooth materials" unit, and the Kachina Group is in the "cratered plains" unit.…”

Section: Ariel's Geologymentioning

confidence: 99%

“…The Pixie Group is mostly found within the "intermediate-age smooth materials" unit, and the Kachina Group is in the "cratered plains" unit. Arielʼs tectonized region near the south pole, including the area between the Kachina Group and Pixie Group, is estimated to be 0.8 (−0.5/+1.8) Ga based on impact crater densities (Kirchoff et al 2022). However, it is unknown what the difference in ages is between the Kachina Group and the Pixie Group.…”

Section: Ariel's Geologymentioning

confidence: 99%

“…These chasmata may have formed because of these events and were then subsequently modified to produce the observed flexure. Furthermore, investigation of impact crater distributions across Ariel's tectonized region in the area between Kachina Chasmata and the Pixie Group found a surface age of only 0.8 Ga (−0.5/+1.8 Ga) (Kirchoff et al 2022). The age of this younger tectonized region near the south pole may reflect the more recent 5:3 MMR between Ariel and Umbriel that is estimated to have occurred ∼1 Ga ago (e.g., Ćuk et al 2020).…”

Section: The Effect Of Lithosphere Compositionmentioning

confidence: 99%

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Ariel's Elastic Thicknesses and Heat Fluxes

Beddingfield¹,

Cartwright²,

Leonard³

et al. 2022

Planet. Sci. J.

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The surface of Ariel displays regions that were resurfaced in the geologically recent past. Some of these regions include large chasmata that exhibit evidence for flexure. To estimate Ariel's heat fluxes, we analyzed flexure associated with the Pixie Group of chasmata, including Pixie, Kewpie, Brownie, Kra, Sylph, and an unnamed chasma, and the Kachina Group of chasmata, which includes Kachina Chasmata. We analyzed topography of these chasmata using digital elevation models developed for this work. Our results indicate that Ariel's elastic thicknesses range between 4.4 ± 0.7 km and 11.4 ± 1.4 km across the imaged surface. The younger Kachina Group has a relatively low elastic thickness of 4.4 ± 0.7 km compared to most chasmata in the older Pixie Group (4.1 ± 0.3 km to 11.4 ± 1.4 km). A pure H2O ice lithosphere would correspond to heat fluxes ranging from 17 to 46 mW m−2 for the Kachina Group and from 6 to 40 mW m−2 for the Pixie Group. Alternatively, if NH3 hydrates are present in Ariel's lithosphere, then the estimated heat fluxes are lower, ranging from 3 to 18 mW m−2 for the Kachina Group and from 1 to 16 mW m−2 for the Pixie Group. These results indicate that accounting for NH3 hydrates in the lithosphere substantially alters the resulting heat flux estimates, which could have important implications for understanding the lithospheric properties of other icy bodies where NH3-bearing species are expected to be present in their lithospheres. Our results are consistent with Ariel experiencing tidal heating generated from mean motion resonances with neighboring satellites in the past, in particular Titania and Miranda.

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Section: Ariel's Geologymentioning

confidence: 99%

Section: Ariel's Geologymentioning

confidence: 99%

Section: The Effect Of Lithosphere Compositionmentioning

confidence: 99%

See 1 more Smart Citation

Ariel's Elastic Thicknesses and Heat Fluxes

Beddingfield¹,

Cartwright²,

Leonard³

et al. 2022

Planet. Sci. J.

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“…At the time of their study there were large uncertainties concerning the size distribution of heliocentric impactors in the outer Solar System. More recent results from the Pluto-Charon system established that the Zahnle et al (2003) "Case A" model impactor distribution largely matches the Kuiper Beltderived impactors (Singer et al 2019), while the steeper "Case B" size-distribution (seen at Neptune and Saturn) is likely to be planetocentric in origin (Kirchoff et al 2022). Crater size-distribution on Uranian moons generally match those on Charon (Kirchoff et al 2022), and are therefore likely to be heliocentric.…”

Section: Satellite Lifetime Against Impactsmentioning

confidence: 94%

“…More recent results from the Pluto-Charon system established that the Zahnle et al (2003) "Case A" model impactor distribution largely matches the Kuiper Beltderived impactors (Singer et al 2019), while the steeper "Case B" size-distribution (seen at Neptune and Saturn) is likely to be planetocentric in origin (Kirchoff et al 2022). Crater size-distribution on Uranian moons generally match those on Charon (Kirchoff et al 2022), and are therefore likely to be heliocentric. We are specifically interested in a steady-state heliocentric impactor population here (as planetocentric bombardment is likely to be highly episodic), and we will assume it corresponds to the Zahnle et al (2003) "Case A" model population.…”

Section: Satellite Lifetime Against Impactsmentioning

confidence: 94%

Cupid Is Not Doomed Yet: On the Stability of the Inner Moons of Uranus

Ćuk,

French,

Showalter

et al. 2022

Preprint

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Some of the small inner moons of Uranus have very closely-spaced orbits. Multiple numerical studies have found that the moons Cressida and Desdemona, within the Portia sub-group, are likely to collide in less than 100 Myr. The subsequent discovery of three new moons (Cupid, Perdita, and Mab) made the system even more crowded. In particular, it has been suggested that the Belinda group (Cupid, Belinda, and Perdita) will become unstable in as little as 10 5 years. Here we revisit the issue of the stability of the inner moons of Uranus using updated orbital elements and considering tidal dissipation. We find that the Belinda group can be stable on 10 8 -year timescales due to an orbital resonance between Belinda and Perdita. We find that tidal evolution cannot form the Belinda-Perdita resonance, but convergent migration could contribute to the long-term instability of the Portia group. We propose that Belinda captured Perdita into the resonance during the last episode of disruption and re-accretion among the inner moons, possibly hundreds of Myr ago.

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Compositions and Interior Structures of the Large Moons of Uranus and Implications for Future Spacecraft Observations

Castillo‐Rogez

Weiss

Beddingfield

et al. 2022

Preprint

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The five large moons of Uranus are important targets for future spacecraft missions. To motivate and inform the exploration of these moons, we model their internal evolution, present-day physical structures, and geochemical and geophysical signatures that may be measured by spacecraft. We predict that if the moons preserved liquid until present, it is likely in the form of residual oceans less than 30 km thick in Ariel, Umbriel, Titania, and Oberon. The preservation of liquid strongly depends on material properties and, potentially, on dynamical circumstances that are unknown. Miranda is unlikely to preserve liquid until present unless it experienced tidal heating a few tens of million years ago. The triaxial shapes estimated from Voyager 2 data for Miranda and Ariel further support the prospect that these moons are internally differentiated with a rocky core and icy shell. We find that since the thin residual layers may be hypersaline, their induced magnetic fields could be detectable by future spacecraft-based magnetometers. However, if the ocean is maintained primarily by ammonia, and thus well below the water freezing point, then its electrical conductivity may be too small to be detectable by spacecraft. Lastly, our calculated tidal Love number (k 2 ) and dissipation factor (Q) are consistent with the Q/k 2 values previously inferred from dynamical evolution models. In particular, we find that the low Q/k 2 estimated for Titania supports the hypothesis that Titania currently holds an ocean.

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Crater Distributions of Uranus's Mid-sized Satellites and Implications for Outer Solar System Bombardment

Cited by 28 publications

References 79 publications

Ariel's Elastic Thicknesses and Heat Fluxes

Ariel's Elastic Thicknesses and Heat Fluxes

Cupid Is Not Doomed Yet: On the Stability of the Inner Moons of Uranus

Compositions and Interior Structures of the Large Moons of Uranus and Implications for Future Spacecraft Observations

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