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Quantitative Rotational to Librational Transition in Dense H<sub>2</sub> and D<sub>2</sub>

Miriam Peña‐Álvarez, Veronika Afonina, Philip Dalladay‐Simpson, Xiaodi Liu, Ross T. Howie, Peter I. C. Cooke, Ioan-Bogdan Magdău, Graeme J. Ackland, Eugene Gregoryanz

2020The Journal of Physical Chemistry Letters21 citationsDOIOpen Access PDF

Abstract

Raman spectroscopy demonstrates that the rotational spectrum of solid hydrogen, and its isotope deuterium, undergoes profound transformations upon compression while still remaining in phase I. We show that these changes are associated with a loss of quantum character in the rotational modes and that the angular momentum J gradually ceases to be a good quantum rotational number. Through isotopic comparisons of the rotational Raman contributions, we reveal that hydrogen and deuterium evolve from a quantum rotor to a harmonic oscillator. We find that the mechanics behind this transformation can be well-described by a quantum-mechanical single inhibited rotor, accurately reproducing the striking spectroscopic changes observed in phase I.

Topics & Concepts

Angular momentumDeuteriumQuantumRotational transitionRaman spectroscopyQuantum numberKinetic isotope effectAtomic physicsHydrogenPhysicsRotor (electric)Rigid rotorSolid hydrogenHarmonic oscillatorChemistryQuantum mechanicsQuantum, superfluid, helium dynamicsMolecular Spectroscopy and StructureHigh-pressure geophysics and materials