Sequential Dual Alignments Introduce Synergistic Effect on Hexagonal Boron Nitride Platelets for Superior Thermal Performance

Planarly aligning 2D platelets is challenging due to their additional orientational freedom compared to 1D materials. This study reports a sequential dual‐alignment approach, employing an extrusion‐printing‐induced shear force and rotating‐magnetic‐field‐induced force couple for platelet planarly al...

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Published in:Advanced materials (Weinheim) 2024-06, Vol.36 (25), p.e2314097-n/a
Main Authors: Chen, Yunxia, Gao, Zhiming, Hoo, Simon A., Tipnis, Varun, Wang, Renjing, Mitevski, Ivan, Hitchcock, Dale, Simmons, Kevin L., Sun, Ya‐Ping, Sarntinoranont, Malisa, Huang, Yong
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Language:English
Subjects:
3D embedded printing
3D printing
Alignment
Boron nitride
Composite materials
dual alignments
Heat conductivity
Heat sinks
Heat transfer
hexagonal boron nitride
MATERIALS SCIENCE
Shear forces
Synergistic effect
Thermal conductivity
two-dimensional material
yield-stress support bath
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cited_by cdi_FETCH-LOGICAL-c4007-adc15eab9179af14d09ea5aa705812635884a48600d5db491b2329242c09e56b3
cites cdi_FETCH-LOGICAL-c4007-adc15eab9179af14d09ea5aa705812635884a48600d5db491b2329242c09e56b3
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container_issue 25
container_start_page e2314097
container_title Advanced materials (Weinheim)
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creator Chen, Yunxia
Gao, Zhiming
Hoo, Simon A.
Tipnis, Varun
Wang, Renjing
Mitevski, Ivan
Hitchcock, Dale
Simmons, Kevin L.
Sun, Ya‐Ping
Sarntinoranont, Malisa
Huang, Yong
description Planarly aligning 2D platelets is challenging due to their additional orientational freedom compared to 1D materials. This study reports a sequential dual‐alignment approach, employing an extrusion‐printing‐induced shear force and rotating‐magnetic‐field‐induced force couple for platelet planarly alignment in a yield‐stress support bath. It is hypothesized that the partial alignment induced by a directional shear force facilitates subsequent axial rotation of the platelets for planar alignment under an external force couple, resulting in a synergistic alignment effect. This sequential dual‐alignment approach achieves better planar alignment of 2D modified hexagonal boron nitride (mhBN). Specifically, the thermal conductivity of the 40 wt% mhBN/epoxy composite is significantly higher (692%) than that of unaligned composites, surpassing the cumulative effect of individual methods (only 133%) with a 5 times more synergistic effect. For 30, 40, and 50 wt% mhBN composites, the thermal conductivity values (5.9, 9.5, and 13.8 W m−1 K−1) show considerable improvement compared to the previously reported highest values (5.3, 6.6, and 8.6 W m−1 K−1). Additionally, a 3D mhBN/epoxy heat sink is printed and evaluated to demonstrate the feasibility of device fabrication. The approach enables the planar alignment of electrically or thermally conducting 2D fillers during 3D fabrication. Platelet partial alignment by a directional shear force facilitates the axial rotation of the platelets for subsequent planar alignment under an external‐force‐couple‐induced torque, and the sequential dual alignments result in a synergistic alignment effect. The realization of planar alignment of hexagonal boron nitride platelets is reported using the sequential dual‐alignment approach when printing in a yield‐stress support bath.
doi_str_mv 10.1002/adma.202314097
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This study reports a sequential dual‐alignment approach, employing an extrusion‐printing‐induced shear force and rotating‐magnetic‐field‐induced force couple for platelet planarly alignment in a yield‐stress support bath. It is hypothesized that the partial alignment induced by a directional shear force facilitates subsequent axial rotation of the platelets for planar alignment under an external force couple, resulting in a synergistic alignment effect. This sequential dual‐alignment approach achieves better planar alignment of 2D modified hexagonal boron nitride (mhBN). Specifically, the thermal conductivity of the 40 wt% mhBN/epoxy composite is significantly higher (692%) than that of unaligned composites, surpassing the cumulative effect of individual methods (only 133%) with a 5 times more synergistic effect. For 30, 40, and 50 wt% mhBN composites, the thermal conductivity values (5.9, 9.5, and 13.8 W m−1 K−1) show considerable improvement compared to the previously reported highest values (5.3, 6.6, and 8.6 W m−1 K−1). Additionally, a 3D mhBN/epoxy heat sink is printed and evaluated to demonstrate the feasibility of device fabrication. The approach enables the planar alignment of electrically or thermally conducting 2D fillers during 3D fabrication. Platelet partial alignment by a directional shear force facilitates the axial rotation of the platelets for subsequent planar alignment under an external‐force‐couple‐induced torque, and the sequential dual alignments result in a synergistic alignment effect. 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subjects 3D embedded printing
3D printing
Alignment
Boron nitride
Composite materials
dual alignments
Heat conductivity
Heat sinks
Heat transfer
hexagonal boron nitride
MATERIALS SCIENCE
Shear forces
Synergistic effect
Thermal conductivity
two-dimensional material
yield-stress support bath
title Sequential Dual Alignments Introduce Synergistic Effect on Hexagonal Boron Nitride Platelets for Superior Thermal Performance
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