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Hauptverfasser: França, Hugo L., Tieman, Daniël, Shemilt, James D., Oishi, Cassio, Jalaal, Maziyar
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2601.09870
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author França, Hugo L.
Tieman, Daniël
Shemilt, James D.
Oishi, Cassio
Jalaal, Maziyar
author_facet França, Hugo L.
Tieman, Daniël
Shemilt, James D.
Oishi, Cassio
Jalaal, Maziyar
contents In direct ink writing (DIW), neighbouring filaments of yield-stress inks are deposited side-by-side and are expected to merge into smooth, mechanically robust structures. Unlike Newtonian filaments, coalescence can arrest in finite time, leaving a permanent, non-flat ridge set by the competition between capillarity and rheology. Here we study the coalescence of two printed yield-stress filaments, combining scaling theory for the arrested state, direct numerical simulations, and DIW experiments on Carbopol gels imaged by optical coherence tomography. In the viscoplastic limit, we predict and observe an approximately linear decrease of the final bridge height with plastocapillary number and a critical yield stress above which coalescence does not initiate. Simulations further show that elasticity becomes important at high plastocapillary number, enabling larger final bridge heights via a crossover from a rigid Herschel--Bulkley solid to a deformable Kelvin--Voigt response. Our findings provide a framework for predicting deposition profiles and, ultimately, for mitigating residual topography in DIW.
format Preprint
id arxiv_https___arxiv_org_abs_2601_09870
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Coalescence of Printed Yield Stress Filaments in Direct Ink Writing
França, Hugo L.
Tieman, Daniël
Shemilt, James D.
Oishi, Cassio
Jalaal, Maziyar
Soft Condensed Matter
In direct ink writing (DIW), neighbouring filaments of yield-stress inks are deposited side-by-side and are expected to merge into smooth, mechanically robust structures. Unlike Newtonian filaments, coalescence can arrest in finite time, leaving a permanent, non-flat ridge set by the competition between capillarity and rheology. Here we study the coalescence of two printed yield-stress filaments, combining scaling theory for the arrested state, direct numerical simulations, and DIW experiments on Carbopol gels imaged by optical coherence tomography. In the viscoplastic limit, we predict and observe an approximately linear decrease of the final bridge height with plastocapillary number and a critical yield stress above which coalescence does not initiate. Simulations further show that elasticity becomes important at high plastocapillary number, enabling larger final bridge heights via a crossover from a rigid Herschel--Bulkley solid to a deformable Kelvin--Voigt response. Our findings provide a framework for predicting deposition profiles and, ultimately, for mitigating residual topography in DIW.
title Coalescence of Printed Yield Stress Filaments in Direct Ink Writing
topic Soft Condensed Matter
url https://arxiv.org/abs/2601.09870