# Impact of surface roughness on liquid-liquid transition

**Authors:** Ken-ichiro Murata, Hajime Tanaka

arXiv: 1703.10353 · 2017-03-31

## TL;DR

This study demonstrates that surface nano-structuring via rubbing significantly influences the kinetics and pattern formation of liquid-liquid transition in a molecular liquid, revealing new control methods for LLT in confined systems.

## Contribution

First experimental investigation showing how surface rubbing affects LLT kinetics and pattern formation, highlighting the role of surface structure in controlling phase transitions.

## Key findings

- Surface rubbing accelerates LLT kinetics.
- Rubbing induces barrier-less formation of liquid II phase.
- Effect disappears in spinodal regime, confirming first-order transition.

## Abstract

Liquid-liquid transition (LLT) in single-component liquids is one of the most mysterious phenomena in condensed matter. So far this problem has attracted attention mainly from the purely scientific viewpoint. Here we report the first experimental study on an impact of surface nano-structuring on LLT by using a surface treatment called rubbing, which is the key technology for the production of liquid crystal displays. We find that such a rubbing treatment has a significant impact on the kinetics of liquid-liquid transition (LLT) of an isotropic molecular liquid, triphenyl phosphite. For a liquid confined between rubbed surfaces, surface-induced barrier-less formation of the liquid II phase is observed even in a metastable state, where there should be a barrier for nucleation of the liquid II phase in bulk. Thus, surface rubbing of substrates not only changes the ordering behavior, but also accelerates the kinetics significantly. This spatio-temporal pattern modulation of LLT can be explained by a wedge filling transition and the resulting drastic reduction of the nucleation barrier. However, this effect completely disappears in the unstable (spinodal) regime, indicating the absence of the activation barrier even for bulk LLT. This confirms the presence of nucleation-growth-type and spinodal-decomposition-type LLT, supporting that LLT is truly a first-order transition with criticality. Our finding also opens up a new way to control the kinetics of LLT of a liquid confined in a solid cell by structuring its surface on a mesoscopic lengthscale, which may contribute to making LLT useful for micro-fluidics and other industrial applications.

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Source: https://tomesphere.com/paper/1703.10353