学术文献库

Characterizing the melting behaviour of monometallic nanoparticles is a great challenge from both the experimental and the theoretical point of view. To this end, we disclose a universal signature based on the cluster's pair distribution function, a measurable quantity from X-ray experimental analysis tools. From a systematic investigation of metallic nanoparticles of different chemical species (Ni, Cu, Pd, Ag, Au and Pt), in a wide size range (146 to 976 atoms), and using both crystalline and five-fold twinned shapes as initial configurations, it emerges that the melting transition is signalled by the disappearance of a peak at the second nearest neighbours in the pair distribution function. To this end, we show that the relative cross-entropy of the pair distribution function between a "cold" and a "hot" reference structure correlates with their caloric curves, thus also presenting a quasi-first order transition at the melting temperature. Finally, we demonstrate the fruitful application of the proposed structural characterization method to identify the melting temperature of nanoparticles in a strongly interacting environment, where low-symmetry solid and melted phases are quasi-degenerate in energy.