Power Laws of Topography and Gravity Spectra of the Solar System Bodies

Ermakov, A.; Park, Ryan; Bills, B. G.

doi:10.1029/2018je005562

Cited by 25 publications

(43 citation statements)

References 105 publications

(151 reference statements)

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“…For example, if we suppose that there is a peak deviatoric stress that scales as Δρ  g  R (where Δρ is a typical density anomaly, g is gravitational acceleration, and R is radius or some comparable large length scale) then we might expect ∝ (  ) −1 ∝ −2 since g scales as R. Note however that this scaling should not be used when going from rocky bodies to icy bodies since the expected peak stresses are lower in ice and the mean density is lower, so the partial success of this scaling for terrestrial bodies does not imply it should work for icy bodies. Recently, Ermakov, et al (2018) reviewed the Kaula rule of different terrestrial bodies in the literature to achieve a more general scaling rule among them. Their result for the gravity spectra is ∝ −1.72 .…”

Section: Gravity Field Resultsmentioning

confidence: 99%

Titan's gravity field and interior structure after Cassini

Durante

Hemingway

Racioppa

et al. 2019

Icarus

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Since its arrival at Saturn in 2004, Cassini performed nine flybys devoted to the determination of Titan's gravity field and its tidal variations. Here we present an updated gravity solution based on the final data set collected during the gravity-dedicated passes, before Cassini's plunge into Saturn's atmosphere. The data set includes an additional flyby (T110, March 2015, primarily devoted to imaging Titan's north polar lakes) carried out with the low-gain antenna. This flyby was particularly valuable because the closest approach occurred at a high latitude (75°N), over an area not previously sampled. Previously published gravity results (Iess, et al., 2012) indicated that Titan is subject to large eccentricity tides in response to the time varying perturbing potential exerted by Saturn. The magnitude of the response quadrupole field, expressed in the tidal Love number k 2 , was used to infer the existence of an internal ocean. The new gravity field determination provides an improved estimate of k 2 of about 0.62, accurate to a level of a few percent. The value is higher than the simplest models of Titan suggest and the interpretation is unclear; possibilities include a high density ocean (as high as 1300 kg/m 3), a partially viscous response of the deeper region, or a dynamic contribution to the tidal response. The new solution includes higher degree and order harmonic coefficients (up to 5) and offers an improved map of gravity anomalies. The geoid is poorly correlated with the topography, implying strong compensation. In addition, the updated geoid and its associated uncertainty could be used to refine the gravity-altimetry correlation analysis and for improved interpretation of radar altimetric data.

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Section: Gravity Field Resultsmentioning

confidence: 99%

Titan's gravity field and interior structure after Cassini

Durante

Hemingway

Racioppa

et al. 2019

Icarus

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“…Thus, the a priori uncertainties on the normalized coefficients of degree l were set using the Kaula rule K/l 2 (Kaula, 1963). This empirical law can successfully describe the gravity power spectrum of the rocky planets, the Moon, and Vesta (Ermakov et al, 2018). Moreover, a good agreement was found for Titan, even if the gravity field is available only up to degree 5 .…”

Section: Resultsmentioning

confidence: 99%

The gravity field and interior structure of Dione

Zannoni,

Hemingway,

Gomez Casajus

et al. 2020

Icarus

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During its mission in the Saturn system, Cassini performed five close flybys of Dione. During three of them, radio tracking data were collected during the closest approach, allowing estimation of the full degree-2 gravity field by precise spacecraft orbit determination.The gravity field of Dione is dominated by J2 and C22, for which our best estimates are J2 x 10 6 = 1496 ± 11 and C22 x 10 6 = 364.8 ± 1.8 (unnormalized coefficients, 1-σ uncertainty). Their ratio is J2/C22 = 4.102 ± 0.044, showing a significative departure (about 17-σ) from the theoretical value of 10/3, predicted for a relaxed body in slow, synchronous rotation around a planet. Therefore, it is not possible to retrieve the moment of inertia directly from the measured gravitational field.The interior structure of Dione is investigated by a combined analysis of its gravity and topography, which exhibits an even larger deviation from hydrostatic equilibrium, suggesting some degree of compensation. The gravity of Dione is far from the expectation for an undifferentiated hydrostatic body, so we built a series of three-layer models, and considered both Airy and Pratt compensation mechanisms. The interpretation is non-unique, but Dione's excess topography may suggest some degree of Airy-type isostasy, meaning that the outer ice shell is underlain by a higher density, lower viscosity layer, such as a subsurface liquid water ocean. The data permit a broad range of possibilities, but the best fitting models tend towards large shell thicknesses and small ocean thicknesses.

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“…We also computed the RMS spectra for the topography, as defined in Ermakov et al (2018). Figure 2 shows the variation of the RMS spectra in blue as well as the difference with the RMS spectra deduced by Ermakov et al (2018). The two estimations are very close to each other, and the difference is below 10 −4 .…”

Section: Observed Shapementioning

confidence: 69%

“…Therefore, in the following, we focus mainly on A 2,0 and use an uncertainty of 0.55 km. We also computed the RMS spectra for the topography, as defined in Ermakov et al (2018). Figure 2 shows the variation of the RMS spectra in blue as well as the difference with the RMS spectra deduced by Ermakov et al (2018).…”

Section: Observed Shapementioning

confidence: 99%

Phoebe’s differentiated interior from refined shape analysis

Rambaux

Castillo‐Rogez

2020

A&A

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Context. Phoebe is an irregular satellite of Saturn, and its origin, from either between the orbits of the giant planets or the Kuiper Belt, is still uncertain. The extent of differentiation of its interior can potentially help inform its formation location because it is mainly determined by heat from 26-aluminum. The internal structure is reflected in the shape, assuming the body is relaxed to hydrostatic equilibrium. Although previous data analysis indicates Phoebe is close to hydrostatic equilibrium, its heavily cratered surface makes it difficult to tease out its low-order shape characteristics. Aims. This paper aims to extract Phoebe’s global shape from the observations returned by the Cassini mission for comparison with uniform and stratified interior models under the assumption of hydrostatic equilibrium. Methods. The global shape is derived from fitting spherical harmonics and keeping only the low-degree harmonics that represent the shape underneath the heavily cratered surface. The hydrostatic theoretical model for shape interpretation is based on the Clairaut equation developed to the third order (although the second order is sufficient in this case). Results. We show that Phoebe is differentiated with a mantle density between 1900 and 2400 kg m−3. The presence of a porous surface layer further restricts the fit with the observed shape. This result confirms the earlier suggestion that Phoebe accreted with sufficient 26-aluminium to drive at least partial differentiation, favoring an origin with C-type asteroids.

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Power Laws of Topography and Gravity Spectra of the Solar System Bodies

Cited by 25 publications

References 105 publications

Titan's gravity field and interior structure after Cassini

Titan's gravity field and interior structure after Cassini

The gravity field and interior structure of Dione

Phoebe’s differentiated interior from refined shape analysis

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