The continuous development of electronic
devices toward high-power
and integrated directions has led to an increasing demand for renewable
polymer composite materials with high thermal conductivity and electrical
insulation to solve the problem of overheating in electronic devices.
Cellulose is inherently insulating, with insufficient thermal conductivity.
Although boron nitride nanosheets (BNNSs) have excellent thermal conductivity,
hexagonal boron nitride (h-BN) ligands in their raw state are prone
to aggregation, which limits their performance. In this work, h-BN
was first ball-milled and amino-modified, and then, carboxylated nanofibrillated
cellulose (COOH-CNF) was used to disperse the BNNSs. With the help
of amide bonding, the BNNSs were uniformly dispersed in the nanocellulose
(CNF) matrix; this reduced the aggregation and the presence of voids
between the BNNSs and promoted the construction of effective thermal
channels. The resulting composite slurry was stably dispersed and
could be filtered to form a film; the best overall performance was
achieved for a BNNS loading of 30% with a thermal conductivity (TC)
of 9.00 W·m–1·K–1 (pure
CNF 1.88 W·m–1·K–1).
In addition, the volume resistivity reached 9.38 × 1013 Ω·cm (pure CNF of 2.53 × 1013 Ω·cm)
and the electrical strength reached 22.67 kV·mm (17.04 kV·mm
for CNF). Our results showed that the BNNS-CNF composite film had
high TC and excellent insulating properties; therefore, its application
in the thermal management of electronic devices has broad application
prospects