Molecular Hydrogen in the N-doped LuH System As a Possible Path to Superconductivity

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Aug 23

PMID 39179540

Authors

Cesare Tresca

Pietro Maria Forcella

Andrea Angeletti

Luigi Ranalli

Cesare Franchini

Michele Reticcioli

Gianni Profeta

Affiliations

Soon will be listed here.

Abstract

The discovery of ambient superconductivity would mark an epochal breakthrough long-awaited for over a century, potentially ushering in unprecedented scientific and technological advancements. The recent findings on high-temperature superconducting phases in various hydrides under high pressure have ignited optimism, suggesting that the realization of near-ambient superconductivity might be on the horizon. However, the preparation of hydride samples tends to promote the emergence of various metastable phases, marked by a low level of experimental reproducibility. Identifying these phases through theoretical and computational methods entails formidable challenges, often resulting in controversial outcomes. In this paper, we consider N-doped LuH as a prototypical complex hydride: By means of machine-learning-accelerated force-field molecular dynamics, we have identified the formation of H molecules stabilized at ambient pressure by nitrogen impurities. Importantly, we demonstrate that this molecular phase plays a pivotal role in the emergence of a dynamically stable, low-temperature, experimental-ambient-pressure superconductivity. The potential to stabilize hydrogen in molecular form through chemical doping opens up a novel avenue for investigating disordered phases in hydrides and their transport properties under near-ambient conditions.

Citing Articles

Synthesis of epitaxial LuN films.

Su G, Xiang S, Bi J, Qi F, Li P, Zhang S Heliyon. 2024; 10(13):e33343.

PMID: 39670234 PMC: 11637054. DOI: 10.1016/j.heliyon.2024.e33343.

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