Litcius/Paper detail

Diffusion-driven transient hydrogenation in metal superhydrides at extreme conditions

Yishan Zhou, Yunhua Fu, Meng Yang, Israel Osmond, Rajesh Jana, Takeshi Nakagawa, Owen Moulding, Jonathan Buhot, Sven Friedemann, Dominique Laniel, Thomas Meier

2025Nature Communications11 citationsDOIOpen Access PDF

Abstract

In recent years, metal hydride research has become one of the driving forces of the high-pressure community, as it is believed to hold the key to superconductivity close to ambient temperature. While numerous novel metal hydride compounds have been reported and extensively investigated for their superconducting properties, little attention has been focused on the atomic and electronic states of hydrogen, the main ingredient in these novel compounds. Here, we present combined 1H- and 139La-NMR data on lanthanum superhydrides, LaHx, (x = 10.2 − 11.1), synthesized after laser heating at pressures above 160 GPa. Strikingly, we found hydrogen to be in a highly diffusive state at room temperature, with diffusion coefficients in the order of 10−6cm2s−1. We found that this diffusive state of hydrogen results in a dynamic de-hydrogenation of the sample over the course of several weeks, approaching a composition similar to its precursor materials. Quantitative measurements demonstrate that the synthesized superhydrides continuously decompose over time. Transport measurements underline this conclusion as superconducting critical temperatures were found to decrease significantly over time as well. This observation sheds new light on formerly unanswered questions on the long-term stability of metal superhydrides. The authors present nuclear magnetic resonance data on lanthanum superhydrides (LaHx) under high pressure. They find that the hydrogen is in a highly diffusive state which results in a dynamic de-hydrogenation of the sample on a time scale of weeks.

Topics & Concepts

Transient (computer programming)DiffusionMaterials scienceComputer scienceThermodynamicsPhysicsOperating systemHydrogen Storage and MaterialsQuantum, superfluid, helium dynamicsNuclear Materials and Properties
Diffusion-driven transient hydrogenation in metal superhydrides at extreme conditions | Litcius