Crystallization Behavior of ZBLAN Glass Under Combined Thermal and Vibrational Effects: Part I -- Experimental Investigation

TL;DR

This study experimentally investigates how mechanical vibration influences the crystallization behavior of ZBLAN glass, revealing that vibration accelerates nucleation and alters crystal morphology, which impacts optical fiber processing.

Contribution

It provides the first systematic experimental analysis of vibration effects on ZBLAN crystallization under normal gravity, highlighting vibration as a nucleation facilitator.

Findings

Vibration lowers crystallization onset temperature.

Morphological transition from needle-like to feather-like crystals.

Increased surface roughness correlates with crystallization.

Abstract

ZBLAN glass is a promising material for infrared optical fibers due to its wide transmission window and low theoretical attenuation. However, its strong tendency to crystallize during processing limits optical performance. While microgravity environments have been shown to suppress crystallization, the role of mechanical vibration under normal gravity conditions remains poorly understood. This study systematically investigates the influence of vibration on the crystallization behavior of ZBLAN using a controlled heating and vibration apparatus. Samples were subjected to varied thermal and vibrational conditions, and their crystallization onset and morphological evolution were examined through optical microscopy, scanning electron microscopy (SEM), energy dispersive X-ray spectroscopy (EDS), and atomic force microscopy (AFM). Results show that vibration reduces the crystallization onset temperature, indicating enhanced atomic mobility and nucleation kinetics. Progressive morphological transitions from needle-like to bow-tie and feather-like crystals were observed with increasing temperature and vibration intensity. Surface roughness analysis corroborates these findings, revealing a significant increase in nanoscale roughness in crystallized regions. Although brief exposure duration and partial thermal decoupling introduced variability among samples, the overall results confirm that vibration acts as a direct facilitator of nucleation rather than a purely thermal effect. This work provides new insight into vibration-induced crystallization in fluoride glasses and establishes the experimental foundation for follow-up modeling and apparatus optimization studies under terrestrial and microgravity conditions.