The gravitational imprint of an interior-orbital resonance in Jupiter-Io

Abstract

At mid-mission perijove 17, NASA's Juno mission has revealed a 7σ discrepancy between Jupiter's observed high-degree tidal response and the theoretical equilibrium tidal response, namely the Love number k42. Here, we propose an interpretation for this puzzling disagreement based on an interior-orbital resonance between internal gravity waves trapped in Jupiter's dilute core and the orbital motion of Io. We use simple Jupiter models to calculate a fractional correction k42 to the equilibrium tidal response that comes from the dynamical tidal response of a g-mode trapped in Jupiter's dilute core. Our results suggest that an extended dilute core (r0.7RJ) produces an interior-orbital resonance with Io that modifies Jupiter's tidal response in k42-11\%, allowing us to fit Juno's k42. In our proposed self-consistent scenario, Jupiter's dilute core evolves in resonant locking with Io's orbital migration, which allows the interior-orbital resonance to persist over geological timescales. This scenario requires a dilute core that becomes smoother or shrinks over time, together with a 42g1 mode (,m,n=4,2,1) with resonant tidal dissipation reaching Q41000. Jupiter's dilute core evolution path and the dissipation mechanism for the resonant 42g1 mode are uncertain and motivate future analysis. No other alternative exists so far to explain the 7σ discrepancy in Juno k42. Our proposed interior-orbital resonance can be tested by Juno observations of k42 tides raised on Jupiter by Europa as obtained at the end of the extended mission (mid 2025), and by future seismological observations of Jupiter's 42g1 mode oscillation frequency.