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The impact of metastability on the high-pressure behavior of cerium.

Created on 14 Jul 2026

Authors

Christopher J Ridley, Alice I Smith, Luke L Daemen, Bianca Haberl

Published in

Nature communications. Volume 17. Issue 1. Jul 13, 2026. Epub Jul 13, 2026.

Abstract

The structures adopted by solids under pressure are often assumed to reflect thermodynamic equilibrium, yet in many materials phase selection is strongly influenced by kinetic pathways and microstructural inheritance. Elemental cerium (Ce) exemplifies this challenge, with decades of conflicting reports describing different high-pressure crystal structures emerging under nominally identical conditions. Here we use neutron diffraction from large ( ~ 60 mm3) sample volumes to follow the structural evolution in ultra-high-purity Ce during controlled pressure-temperature cycling between 85 and 295 K and up to 8 GPa. We find that the crystal structure formed at high pressure depends on the compression pathway: slow compression ( ~ 0.25 GPa hr-1) at room temperature favors an orthorhombic phase ( α ' ), whereas slow ( ~ 0.25 GPa hr-1) and also moderately faster ( ~ 0.5 GPa hr-1) compression at low temperature stabilizes a pure monoclinic phase (α). The low-temperature phase persists metastably over a wide temperature range but transforms irreversibly upon heating above  ~ 280 K, or modest pressure cycling. Remarkably, the lower-pressure γ phase remains trapped far beyond the expected stability field, persisting to the highest pressures studied. These observations show that phase selection in Ce is governed by kinetics and microstructural memory rather than equilibrium thermodynamics or sample morphology alone, establishing path dependence as a defining feature of its high-pressure behavior.

PMID:
42443178
Bibliographic data and abstract were imported from PubMed on 14 Jul 2026.

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