MXene-Coated Liquid Metal Nanodroplet Aggregates

MXene-Coated Liquid Metal Nanodroplet Aggregates

Combining droplets of liquid metal (LM) with nanomaterials often introduces synergistic thermal or electrical properties that are not found in the constituent materials alone. However, in these existing systems, LM droplets maintain a statistically uniform dispersion and are not capable of self-asse...

Full description

Saved in:
Bibliographic Details
Main Author: Mason Zadan (8667870) (author)
Other Authors: Yafeng Hu (5894) (author), Jeremiah Lipp (13803586) (author), Michael Vinciguerra (14208644) (author), Neal Lewis (20940406) (author), Dylan Shah (7538441) (author), Mohammad F. Islam (1397083) (author), Dhriti Nepal (1289034) (author), Matthew Grasinger (19746035) (author), Kaushik Dayal (839065) (author), Christopher Tabor (2094922) (author), Carmel Majidi (4168429) (author)
Published: 2025
Subjects:
Medicine
Physiology
Pharmacology
Biotechnology
Evolutionary Biology
Ecology
Infectious Diseases
Space Science
Chemical Sciences not elsewhere classified
Physical Sciences not elsewhere classified
wearable electronic applications
statistically uniform dispersion
small volume fractions
high volume fractions
filler material required
decreasing interfacial thickness
constituent materials alone
25 vol %)
unique lm morphology
coating nanoscale droplets
avoiding lm rupture
lm droplets maintain
based composites exhibit
introducing lm leaking
thermal interface materials
mxene nanosheets alone
form semisolid aggregates
soft lm composites
3 </ sub
2 </ sub
x </
assembled aggregates
droplets self
effective composites
sub ><
></ sub
form self
thermal management
printed electronics
liquid metal
introducing aggregation
exponential increase
existing systems
electrical properties
electrical conductivity
electric resistance
design parameter
could enable
change dramatically
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Combining droplets of liquid metal (LM) with nanomaterials often introduces synergistic thermal or electrical properties that are not found in the constituent materials alone. However, in these existing systems, LM droplets maintain a statistically uniform dispersion and are not capable of self-assembly or aggregation. These composites are limited by their need for high volume fractions of LM (>60 vol %) to achieve high thermal properties, introducing LM leaking as a drawback for thermal management and wearable electronic applications. In this work, we show that coating nanoscale droplets of eutectic gallium–indium (EGaIn) LM with small volume fractions of Ti<sub>3</sub>C<sub>2</sub>T<sub><i>x</i></sub> MXenes (0.25 vol %) results in a unique LM morphology in which droplets self-assemble to form semisolid aggregates. This is accomplished by wrapping MXene sheets around individual LM droplets to create “sticky” particles that form self-assembled aggregates when mixed with a silicone oil. By introducing aggregation as a design parameter in soft LM composites, the thermal and electric resistance of the composite is shown to change dramatically. In contrast to silicone-based composites containing LM droplets or MXene nanosheets alone, these MXene-LM-silicone-based composites exhibit an exponential increase in thermal and electrical conductivity with decreasing interfacial thickness with significantly lower LM volume fractions (25 vol %) while avoiding LM rupture and bleed-out. This could enable more effective composites, reducing the amount of filler material required for thermal interface materials (TIM) and printed electronics.

Similar Items