Litcius/Paper detail

Double superionicity in icy compounds at planetary interior conditions

Kyla de Villa, Felipe González‐Cataldo, Burkhard Militzer

2023Nature Communications20 citationsDOIOpen Access PDF

Abstract

Abstract The elements hydrogen, carbon, nitrogen and oxygen are assumed to comprise the bulk of the interiors of the ice giant planets Uranus, Neptune, and sub-Neptune exoplanets. The details of their interior structures have remained largely unknown because it is not understood how the compounds H 2 O, NH 3 and CH 4 behave and react once they have been accreted and exposed to high pressures and temperatures. Here we study thirteen H-C-N-O compounds with ab initio computer simulations and demonstrate that they assume a superionic state at elevated temperatures, in which the hydrogen ions diffuse through a stable sublattice that is provided by the larger nuclei. At yet higher temperatures, four of the thirteen compounds undergo a second transition to a novel doubly superionic state, in which the smallest of the heavy nuclei diffuse simultaneously with hydrogen ions through the remaining sublattice. Since this transition and the melting transition at yet higher temperatures are both of first order, this may introduce additional layers in the mantle of ice giant planets and alter their convective patterns.

Topics & Concepts

UranusAstrobiologyNeptuneHydrogenPlanetChemical physicsGas giantIonOxygenExoplanetChemistryMaterials sciencePhysicsAstrophysicsOrganic chemistryHigh-pressure geophysics and materialsAdvanced Chemical Physics StudiesAstro and Planetary Science