Litcius/Paper detail

Observation of plastic ice VII by quasi-elastic neutron scattering

Maria Rescigno, Alberto Toffano, Umbertoluca Ranieri, L. Andriambariarijaona, Richard Gaál, Stefan Klotz, Michael Marek Koza, Jacques Ollivier, Fausto Martelli, John Russo, Francesco Sciortino, J. Teixeira, L. E. Bove

2025Nature16 citationsDOIOpen Access PDF

Abstract

Abstract Water is the third most abundant molecule in the universe and a key component in the interiors of icy moons, giant planets and Uranus- and Neptune-like exoplanets 1–3 . Owing to its distinct molecular structure and flexible hydrogen bonds that readily adapt to a wide range of pressures and temperatures, water forms numerous crystalline and amorphous phases 4–6 . Most relevant for the high pressures and temperatures of planetary interiors is ice VII (ref. 4 ), and simulations have identified along its melting curve the existence of a so-called plastic phase 7–12 in which individual molecules occupy fixed positions as in a solid yet are able to rotate as in a liquid. Such plastic ice has not yet been directly observed in experiments. Here we present quasi-elastic neutron scattering measurements, conducted at temperatures between 450 and 600 K and pressures up to 6 GPa, that reveal the existence of a body-centred cubic structure, as found in ice VII, with water molecules showing picosecond rotational dynamics typical for liquid water. Comparison with molecular dynamics simulations indicates that this plastic ice VII does not conform to a free rotor phase but rather shows rapid orientational jumps, as observed in jump-rotor plastic crystals 13,14 . We anticipate that our observation of plastic ice VII will affect our understanding of the geodynamics of icy planets and the differentiation processes of large icy moons.

Topics & Concepts

Neutron scatteringNeutronPhysicsSmall-angle neutron scatteringNuclear physicsMaterials scienceGeologyInorganic Fluorides and Related CompoundsMaterial Dynamics and PropertiesEarthquake Detection and Analysis