Mixing Effects in the Crystallization of Supercooled Quantum Binary Liquids

Abstract

By means of Raman spectroscopy of liquid microjets we have investigated the crystallization process of supercooled quantum liquid mixtures composed of parahydrogen (pH2) diluted with small amounts of up to 5\% of either neon or orthodeuterium (oD2), and of oD2 diluted with either Ne or pH2. We show that the introduction of Ne impurities affects the crystallization kinetics in both the pH2-Ne and oD2-Ne mixtures in terms of a significant reduction of the crystal growth rate, similarly to what found in our previous work on supercooled pH2-oD2 liquid mixtures [M. K\"uhnel et al., Phys. Rev. B 89, 180506(R) (2014)]. Our experimental results, in combination with path-integral simulations of the supercooled liquid mixtures, suggest in particular a correlation between the measured growth rates and the ratio of the effective particle sizes originating from quantum delocalization effects. We further show that the crystalline structure of the mixture is also affected to a large extent by the presence of the Ne impurities, which likely initiate the freezing process through the formation of Ne crystallites.