Salvato in:
Dettagli Bibliografici
Autori principali: Ishikawa, Rikuya, Takae, Kyohei, Takegami, Daisuke, Mizuguchi, Yoshikazu, Kurita, Rei
Natura: Preprint
Pubblicazione: 2026
Soggetti:
Accesso online:https://arxiv.org/abs/2603.26132
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866914426478657536
author Ishikawa, Rikuya
Takae, Kyohei
Takegami, Daisuke
Mizuguchi, Yoshikazu
Kurita, Rei
author_facet Ishikawa, Rikuya
Takae, Kyohei
Takegami, Daisuke
Mizuguchi, Yoshikazu
Kurita, Rei
contents Multicomponent crystals are often assumed to form nearly random solid solutions when thermodynamically stable. However, crystal growth proceeds from structurally heterogeneous liquids, raising the possibility that the liquid state may influence which species are incorporated into the growing crystal. Here we demonstrate that liquid-state structural asymmetry can induce species-selective crystallization in multicomponent systems. Using molecular dynamics simulations of a multivalent rocksalt-type model (AgPbBiTe$_3$), we find that cations with higher valence readily form locally crystal-compatible coordination environments in the liquid and are efficiently incorporated into the growing lattice, whereas lower-valence cations exhibit more disordered liquid coordination and attach less efficiently at the crystal-liquid interface. This asymmetry leads to species-selective incorporation and slower crystal growth. Depth-resolved photoelectron spectroscopy measurements on AgPbBiTe$_3$ further reveal enhanced Ag concentration near grain-boundary and surface regions, consistent with the selective incorporation predicted by the simulations. These results demonstrate that structural compatibility between liquid-state structure and the target crystal motif governs selective incorporation during crystallization, providing a general kinetic mechanism by which compositional heterogeneity can emerge during growth of multicomponent crystals.
format Preprint
id arxiv_https___arxiv_org_abs_2603_26132
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Liquid-state structural asymmetry governs species-selective crystallization in multicomponent systems
Ishikawa, Rikuya
Takae, Kyohei
Takegami, Daisuke
Mizuguchi, Yoshikazu
Kurita, Rei
Soft Condensed Matter
Materials Science
Statistical Mechanics
Multicomponent crystals are often assumed to form nearly random solid solutions when thermodynamically stable. However, crystal growth proceeds from structurally heterogeneous liquids, raising the possibility that the liquid state may influence which species are incorporated into the growing crystal. Here we demonstrate that liquid-state structural asymmetry can induce species-selective crystallization in multicomponent systems. Using molecular dynamics simulations of a multivalent rocksalt-type model (AgPbBiTe$_3$), we find that cations with higher valence readily form locally crystal-compatible coordination environments in the liquid and are efficiently incorporated into the growing lattice, whereas lower-valence cations exhibit more disordered liquid coordination and attach less efficiently at the crystal-liquid interface. This asymmetry leads to species-selective incorporation and slower crystal growth. Depth-resolved photoelectron spectroscopy measurements on AgPbBiTe$_3$ further reveal enhanced Ag concentration near grain-boundary and surface regions, consistent with the selective incorporation predicted by the simulations. These results demonstrate that structural compatibility between liquid-state structure and the target crystal motif governs selective incorporation during crystallization, providing a general kinetic mechanism by which compositional heterogeneity can emerge during growth of multicomponent crystals.
title Liquid-state structural asymmetry governs species-selective crystallization in multicomponent systems
topic Soft Condensed Matter
Materials Science
Statistical Mechanics
url https://arxiv.org/abs/2603.26132