Equilibrium Tidal Response of Jupiter: Detectability by the Juno Spacecraft

Wahl, S. M.; Parisi, Marzia; Folkner, W. M.; Hubbard, W. B.; Militzer, Burkhard

doi:10.3847/1538-4357/ab6cf9

Cited by 28 publications

(63 citation statements)

References 49 publications

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“…For a distant perturber, the m = 2 moment dominates the expansion, but higher-order moments become more significant as a 0 /R increases. We note that the Jupiter and Saturn k 22 reported later for comparison defined k nm with q tid,e instead of q tid,0 (Wahl et al 2017a(Wahl et al , 2020.…”

Section: Methodsmentioning

confidence: 80%

“…S is added to Equation (1), and equipotential surfaces for the combined potential are evaluated on a 3D grid r(r, μ, f). Wahl et al (2020) updated the 3D CMS method by modifying W by subtracting out a linear term determined by an average force,…”

Section: Methodsmentioning

confidence: 99%

“…Hubbard (2013) introduced the CMS technique, a nonperturbative, iterative method for more precise calculations of selfconsistent shape and gravitational field. The CMS method was subsequently extended to three dimensions and applied to the cases of Jupiter and Saturn (Wahl et al 2016(Wahl et al , 2017aNettelmann 2019;Wahl et al 2020). In this work, we apply the CMS method to hot Jupiter exoplanets for the first time.…”

Section: Introductionmentioning

confidence: 99%

“…While more computationally expensive than the theory of figures, the CMS method correctly accounts for nonlinear effects that become relevant for extremely deformed planets, most notably effects on the order of the product of rotational and tidal perturbations (Wahl et al 2017a). These nonlinear effects lead to a splitting of the static k nm with degree m and an enhancement of k 22 that is significant for Jupiter and Saturn (Lainey et al 2017(Lainey et al , 2020Durante et al 2020;Wahl et al 2020).…”

Section: Introductionmentioning

confidence: 99%

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Tidal Response and Shape of Hot Jupiters

Wahl

Thorngren

et al. 2021

ApJ

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We study the response of hot Jupiters to a static tidal perturbation using the concentric MacLaurin spheroid method. For strongly irradiated planets, we first performed radiative transfer calculations to relate the planet’s equilibrium temperature, T eq, to its interior entropy. We then determined the gravity harmonics, shape, moment of inertia, and static Love numbers for a range of two-layer interior models that assume a rocky core plus a homogeneous and isentropic envelope composed of hydrogen, helium, and heavier elements. We identify general trends and then study HAT-P-13b, the WASP planets 4b, 12b, 18b, 103b, and 121b, and Kepler-75b and CoRot-3b. We compute the Love numbers, k nm , and transit radius correction, ΔR, which we compare with predictions in the literature. We find that the Love number, k 22, of tidally locked giant planets cannot exceed a value of 0.6, and that the high T eq consistent with strongly irradiated hot Jupiters tends to further lower k 22. While most tidally locked planets are well described by a linear regime response of k 22 = 3J 2/q 0 (where q 0 is the rotation parameter of the gravitational potential), for extreme cases such as WASP-12b, WASP-103b, and WASP-121b, nonlinear effects can account for over 10% of the predicted k 22. The k 22 values larger than 0.6, as they have been reported for planets WASP-4b and HAT-P13B, cannot result from a static tidal response without extremely rapid rotation and thus are inconsistent with their expected tidally locked state.

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Section: Methodsmentioning

confidence: 80%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Tidal Response and Shape of Hot Jupiters

Wahl

Thorngren

et al. 2021

ApJ

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“…3 of 12 10.1029/2020JE006416 The dynamical model used to integrate the Juno trajectory for orbit determination purposes accounts for several effects due to gravitational and nongravitational forces acting on the spacecraft. A nonexhaustive list is: the mass of Jupiter, the Sun and the other planets (Folkner, 2019); Jupiter's rotational parameters (Archinal et al, 2010); Jupiter's zonal harmonic coefficients from degree 2 to 12 (Iess et al, 2018); tidal perturbations caused by the Galilean satellites up to degree 6 (Wahl et al, 2020); the mass of the Galilean satellites (Jacobson, 2013); solar pressure radiation; Jupiter's albedo and thermal emission from the planet.…”

Section: The Spherical Harmonic Coefficients Of Jupiter's Gravity Fieldmentioning

confidence: 99%

Resolving the Latitudinal Short‐Scale Gravity Field of Jupiter Using Slepian Functions

et al. 2020

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Early gravity measurements performed by the Juno spacecraft determined Jupiter's low‐degree gravity harmonics, including the first estimate of the planet's north‐south asymmetric field. The retrieved information was used to infer that the strong zonal winds visible at the cloud tops must extend down a few thousand kilometers, where they are suppressed in the deep interior. The next frontier for the Juno gravity experiment includes, among other goals, the determination of Jupiter's small‐scale gravity field with high accuracy, and its relation to atmospheric circulation at shorter length scales. The geometry of the Juno closest approaches to the planet poses a challenge to this task, as they span latitudes between 4°N and 29°N over the course of the nominal mission. Since Doppler measurements are the most sensitive to gravity anomalies when the spacecraft is close to the body, observations of Jupiter's gravity field are mostly concentrated in the northern hemisphere, while the traditional spherical harmonic functions are not orthonormal over a latitudinal subdomain. Here we define customized Slepian functions, which are orthogonal in a specific latitude range and are optimized to represent Jupiter's local surface gravity at north latitudes. We show that with the new functions, the short‐scale latitudinal variability of the gravity field is resolved with high accuracy between 15°S and 45°N latitude. Furthermore, preliminary results show that the estimated values for the Slepian coefficients from the Juno data match the predictions obtained using thermal wind balance to relate the dynamical density anomalies and the winds with an optimized scale height.

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