Effect of Enceladus's rapid synchronous spin on interpretation of Cassini gravity

William B. McKinnon

doi:10.1002/2015GL063384

Effect of Enceladus's rapid synchronous spin on interpretation of Cassini gravity

William B. McKinnon

Department of Earth & Planetary Sciences

Research output: Contribution to journal › Article › peer-review

113 Scopus citations

Abstract

Enceladus's degree 2 gravity, determined by Cassini, is nominally nonhydrostatic to 3σ (J₂/C₂₂ = 3.38-3.63, as opposed to 10/3). Iess et al. (2014) interpret this in terms of a hydrostatic interior (core) and isostatic (not hydrostatic) floating ice shell. Enceladus's rapid (1.37 d) synchronous spin and tide distorts its shape substantially, though, enough that the predicted hydrostatic J₂/C₂₂ is not 10/3 but closer to 3.25. This leads to the following revision to the internal picture of Enceladus, compared with Iess et al.: (1) the satellite's core is somewhat smaller and slightly denser (190 km radius and 2450 kg/m³); (2) the compensation depth (shell thickness) of the global (degree 2) ice shell is ≈ 50 km, rather close to the base of the modeled ice + water layer; and (3) the compensation depth (shell thickness) beneath the South Polar Terrain (from J₃) remains shallower (thinner) at ≈ 30 km, independent of but influenced by the degree 2 solution.

Original language	English
Pages (from-to)	2137-2143
Number of pages	7
Journal	Geophysical Research Letters
Volume	42
Issue number	7
DOIs	https://doi.org/10.1002/2015GL063384
State	Published - Apr 16 2015

Keywords

Cassini mission
Enceladus ocean
gravity model
icy satellite

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10.1002/2015GL063384

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title = "Effect of Enceladus's rapid synchronous spin on interpretation of Cassini gravity",

abstract = "Enceladus's degree 2 gravity, determined by Cassini, is nominally nonhydrostatic to 3σ (J2/C22 = 3.38-3.63, as opposed to 10/3). Iess et al. (2014) interpret this in terms of a hydrostatic interior (core) and isostatic (not hydrostatic) floating ice shell. Enceladus's rapid (1.37 d) synchronous spin and tide distorts its shape substantially, though, enough that the predicted hydrostatic J2/C22 is not 10/3 but closer to 3.25. This leads to the following revision to the internal picture of Enceladus, compared with Iess et al.: (1) the satellite's core is somewhat smaller and slightly denser (190 km radius and 2450 kg/m3); (2) the compensation depth (shell thickness) of the global (degree 2) ice shell is ≈ 50 km, rather close to the base of the modeled ice + water layer; and (3) the compensation depth (shell thickness) beneath the South Polar Terrain (from J3) remains shallower (thinner) at ≈ 30 km, independent of but influenced by the degree 2 solution.",

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journal = "Geophysical Research Letters",

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T1 - Effect of Enceladus's rapid synchronous spin on interpretation of Cassini gravity

AU - McKinnon, William B.

PY - 2015/4/16

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N2 - Enceladus's degree 2 gravity, determined by Cassini, is nominally nonhydrostatic to 3σ (J2/C22 = 3.38-3.63, as opposed to 10/3). Iess et al. (2014) interpret this in terms of a hydrostatic interior (core) and isostatic (not hydrostatic) floating ice shell. Enceladus's rapid (1.37 d) synchronous spin and tide distorts its shape substantially, though, enough that the predicted hydrostatic J2/C22 is not 10/3 but closer to 3.25. This leads to the following revision to the internal picture of Enceladus, compared with Iess et al.: (1) the satellite's core is somewhat smaller and slightly denser (190 km radius and 2450 kg/m3); (2) the compensation depth (shell thickness) of the global (degree 2) ice shell is ≈ 50 km, rather close to the base of the modeled ice + water layer; and (3) the compensation depth (shell thickness) beneath the South Polar Terrain (from J3) remains shallower (thinner) at ≈ 30 km, independent of but influenced by the degree 2 solution.

AB - Enceladus's degree 2 gravity, determined by Cassini, is nominally nonhydrostatic to 3σ (J2/C22 = 3.38-3.63, as opposed to 10/3). Iess et al. (2014) interpret this in terms of a hydrostatic interior (core) and isostatic (not hydrostatic) floating ice shell. Enceladus's rapid (1.37 d) synchronous spin and tide distorts its shape substantially, though, enough that the predicted hydrostatic J2/C22 is not 10/3 but closer to 3.25. This leads to the following revision to the internal picture of Enceladus, compared with Iess et al.: (1) the satellite's core is somewhat smaller and slightly denser (190 km radius and 2450 kg/m3); (2) the compensation depth (shell thickness) of the global (degree 2) ice shell is ≈ 50 km, rather close to the base of the modeled ice + water layer; and (3) the compensation depth (shell thickness) beneath the South Polar Terrain (from J3) remains shallower (thinner) at ≈ 30 km, independent of but influenced by the degree 2 solution.

KW - Cassini mission

KW - Enceladus ocean

KW - gravity model

KW - icy satellite

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DO - 10.1002/2015GL063384

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VL - 42

SP - 2137

EP - 2143

JO - Geophysical Research Letters

JF - Geophysical Research Letters

IS - 7

ER -

Effect of Enceladus's rapid synchronous spin on interpretation of Cassini gravity

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Keywords

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