Aqueous suspensions of glass silicate dielectric powders for ink-jet printing applications

Ink-jet printing (IJP) is a rapid prototyping method which is very promising for the manufacturing of multilayer hybrid circuits. Before the formulation of inks, the first step aims to ensure the stability of dielectric powder suspensions with the specifications required for the IJP process in terms...

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Published in:Powder technology 2014-11, Vol.266, p.303-311
Main Authors: Singlard, M., Aimable, A., Lejeune, M., Dossou-Yovo, C., Poncelet, M., Noguéra, R., Modes, C.
Format: Article
Language:English
Subjects:
Applied sciences
Attrition milling
Chemical engineering
Chemical Sciences
Dispersion
Engineering Sciences
Exact sciences and technology
Ink-jet printing
Liquid-liquid and fluid-solid mechanical separations
Material chemistry
Miscellaneous
Multilayer hybrid circuit
Settling
Solid-solid systems
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cited_by cdi_FETCH-LOGICAL-c370t-9130baed9af9cb74737103365c26fa841c6b7ca84d96f9f2e167fe67ec3b41313
cites cdi_FETCH-LOGICAL-c370t-9130baed9af9cb74737103365c26fa841c6b7ca84d96f9f2e167fe67ec3b41313
container_end_page 311
container_issue
container_start_page 303
container_title Powder technology
container_volume 266
creator Singlard, M.
Aimable, A.
Lejeune, M.
Dossou-Yovo, C.
Poncelet, M.
Noguéra, R.
Modes, C.
description Ink-jet printing (IJP) is a rapid prototyping method which is very promising for the manufacturing of multilayer hybrid circuits. Before the formulation of inks, the first step aims to ensure the stability of dielectric powder suspensions with the specifications required for the IJP process in terms of solid content, particle size, rheology, and stability versus sedimentation. A commercial glass silicate powder currently used as a dielectric material was studied during an attrition milling (i) for low ceramic loading (3vol.%) and (ii) for significant ceramic loading (20vol.%) with different dispersants: polyelectrolytes with carboxylate groups, and sulfate groups. The milling step impact on the surface chemistry of the powder was investigated in both cases. A potassium polycarboxylate was found to be the most efficient dispersant, and the optimization of the dispersant rate was carried out through zeta potential measurements, viscosity, dispersant adsorbed rate, and sedimentation tests. An attempt of correlation between some of these properties is proposed. The preliminary ejection tests obtained with an ink prepared from an optimized suspension allowed to generate a wide range of drop velocity (0.7 to 4.2m/s) and drop diameter (47 to 56μm), which will be useful in a further step to optimize the characteristics of green ink-jet printed dielectric layers. The purpose of this paper is the formulation of an aqueous suspension from a commercial ceramic dielectric powder, matching the ink-jet printing process requirements, for LTCC applications. Chemico-physical investigations were carried out to understand stabilization mechanisms in order to optimize the formulation of high ceramic loading suspension (20vol.%). [Display omitted] •Formulation of an aqueous dielectric suspension with required specifications for IJP.•Study of hydrolysis mechanisms during powder attrition milling.•The most efficient dispersant was found with zeta and conductivity measurements.•Other dispersants were found inefficient with correlatively complexation mechanisms.•Optimized formulation could be transferred to highly loaded suspension (20vol.%).
doi_str_mv 10.1016/j.powtec.2014.06.044
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subjects Applied sciences
Attrition milling
Chemical engineering
Chemical Sciences
Dispersion
Engineering Sciences
Exact sciences and technology
Ink-jet printing
Liquid-liquid and fluid-solid mechanical separations
Material chemistry
Miscellaneous
Multilayer hybrid circuit
Settling
Solid-solid systems
title Aqueous suspensions of glass silicate dielectric powders for ink-jet printing applications
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