Saved in:
Bibliographic Details
Main Authors: Jin, Chenyu, Chen, Guoxiang, Wang, Beibei, Mei, Yongfeng, Riegler, Hans
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.15104
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909993848012800
author Jin, Chenyu
Chen, Guoxiang
Wang, Beibei
Mei, Yongfeng
Riegler, Hans
author_facet Jin, Chenyu
Chen, Guoxiang
Wang, Beibei
Mei, Yongfeng
Riegler, Hans
contents Melting is typically viewed as a bulk first-order phase transition that proceeds once nucleation barriers are overcome. Here we demonstrate an interfacially arrested melting regime in molecularly thin crystalline films, where large liquid droplets remain stably trapped well above the bulk melting temperature. Using long-chain alkane films as a model system, we show that melting is suspended by the competition between bulk melting enthalpy and interfacial energy costs associated with capillary confinement. The arrested state is governed by a single control parameter, the product of temperature offset and film thickness, and is independent of droplet size. As a consequence, small temperature variations produce pronounced and reversible changes in droplet morphology, enabling intrinsic thermodynamic amplification of thermal signals. These results reveal a general mechanism by which interfacial constraints can arrest first-order phase transitions in thin films.
format Preprint
id arxiv_https___arxiv_org_abs_2508_15104
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Interfacially arrested melting in thin films: capillarity-driven suspension of phase transitions
Jin, Chenyu
Chen, Guoxiang
Wang, Beibei
Mei, Yongfeng
Riegler, Hans
Soft Condensed Matter
Materials Science
Melting is typically viewed as a bulk first-order phase transition that proceeds once nucleation barriers are overcome. Here we demonstrate an interfacially arrested melting regime in molecularly thin crystalline films, where large liquid droplets remain stably trapped well above the bulk melting temperature. Using long-chain alkane films as a model system, we show that melting is suspended by the competition between bulk melting enthalpy and interfacial energy costs associated with capillary confinement. The arrested state is governed by a single control parameter, the product of temperature offset and film thickness, and is independent of droplet size. As a consequence, small temperature variations produce pronounced and reversible changes in droplet morphology, enabling intrinsic thermodynamic amplification of thermal signals. These results reveal a general mechanism by which interfacial constraints can arrest first-order phase transitions in thin films.
title Interfacially arrested melting in thin films: capillarity-driven suspension of phase transitions
topic Soft Condensed Matter
Materials Science
url https://arxiv.org/abs/2508.15104