Facile Low-Oxidation Emulsification of Liquid Metal Using Polyvinylpyrrolidone for Highly Viscoelastic Heat Conductive Pastes

Facile Low-Oxidation Emulsification of Liquid Metal Using Polyvinylpyrrolidone for Highly Viscoelastic Heat Conductive Pastes

Low-melting-point metals, known as liquid metals (LMs), have recently attracted significant interest owing to their high conductivity and fluidity. “Emulsification” of LMs into colloidal microdroplets in immiscible carrier fluids confers a variety of unique opportunities in terms of their processabi...

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Bibliographic Details
Main Author: Suji Kim (1807360) (author)
Other Authors: Jiyoon Park (5142071) (author), Yong Hui Pi (20142299) (author), Jun Su Park (16992283) (author), Yern Seung Kim (1385661) (author), Kai Wu (221862) (author), Guihua Yu (1440559) (author), Joohyung Lee (1488208) (author)
Published: 2024
Subjects:
Biophysics
Medicine
Biotechnology
Developmental Biology
Infectious Diseases
Space Science
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
thermal interface materials
interdroplet percolation network
directed thermal transport
insulating oxide skin
lm droplets coated
highly viscoelastic lm
given lm load
“ emulsification ”
high lm loads
resulting emulsions presents
surface oxide skin
resulting emulsions
oxide layer
high conductivity
etoh emulsions
oxidation emulsification
emulsification efficiency
achieving emulsification
unique opportunities
significantly modifying
resulting pvp
relevant applications
potentially useful
point metals
often deteriorates
markedly increases
liquid metals
interfacial dynamics
free counterparts
facile low
considerable challenge
colloidal microdroplets
applied shear
adsorbed pvps
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Summary:Low-melting-point metals, known as liquid metals (LMs), have recently attracted significant interest owing to their high conductivity and fluidity. “Emulsification” of LMs into colloidal microdroplets in immiscible carrier fluids confers a variety of unique opportunities in terms of their processability as well as functionality; however, achieving emulsification at high LM loads while significantly modifying the rheology of the resulting emulsions presents a considerable challenge. Furthermore, the formation of a surface oxide skin on emulsified LM droplets complicates their interfacial dynamics and often deteriorates the performance of the resulting emulsions. In this study, we demonstrate that polyvinylpyrrolidone (PVP), which can coordinate-bond with LM, markedly increases the emulsification efficiency of LM in ethanol (EtOH), thereby enabling the formation of highly viscoelastic LM-in-EtOH emulsion pastes via simple shear mixing using a mortar and pestle. The growth of the oxide layer is controlled by the surface-adsorbed PVPs, which form an interdroplet percolation network. The resulting PVP-mediated “structured” emulsions exhibit significantly higher thermal conductivities than their additive-free counterparts under a given LM load, owing to the formation of an effective thermal transport network of interconnected conductive LM droplets with controlled growth of insulating oxide skin. Industry-relevant blade coating using these LM-in-EtOH emulsions is demonstrated, during which LM droplets coated on nonstretchable substrates readily develop anisotropy under applied shear, which may be potentially useful for directed thermal transport in relevant applications. Lastly, the performance of the LM droplets coated with PVP as thermal interface materials is evaluated.

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