TY - JOUR
T1 - Controllable Frontal Polymerization and Spontaneous Patterning Enabled by Phase-Changing Particles
AU - Gao, Yuan
AU - Dearborn, Mason A.
AU - Hemmer, Julie
AU - Wang, Zhao
AU - Esser-Kahn, Aaron P.
AU - Geubelle, Philippe H.
N1 - Funding Information:
Y.G. and M.A.D. contributed equally to this work. This work was supported by the U. S. Air Force Office of Scientific Research through Award FA9550‐20‐1‐0194 as part of the Center of Excellence in Self‐healing and Morphogenic Manufacturing. The authors also acknowledge the support of the National Science Foundation for Grant No. 1933932 through the GOALI: Manufacturing USA: Energy Efficient Processing of Thermosetting Polymers and Composites. The authors again acknowledge the assistance from Dr. Vytas Bindokas at the University of Chicago Integrated Light Microscopy Facility with confocal microscope scanning.
Publisher Copyright:
© 2021 Wiley-VCH GmbH
PY - 2021/10/21
Y1 - 2021/10/21
N2 - Frontal polymerization provides a rapid, economic, and environmentally friendly methodology to manufacture thermoset polymers and composites. Despite its efficiency and reduced environmental impact, the manufacturing method is underutilized due to the limited fundamental understanding of its dynamic control. This work reports the control and patterning of the front propagation in a dicyclopentadiene resin by immersion of phase-changing polycaprolactone particles. Predictive and designed patterning is enabled by multiphysical numerical analyses, which reveal that the interplay between endothermic phase transition, exothermic chemical reaction, and heat exchange govern the temperature, velocity, and propagation path of the front via two different interaction regimes. To pattern the front, one can vary the size and spacing between the particles and increase the number of propagating fronts, resulting in tunable physical patterns formed due to front separation and merging near the particles. Both single- and double-frontal polymerization experiments in an open mold are performed. The results confirm the front–particle interaction mechanisms and the shapes of the patterns explored numerically. The present study offers a fundamental understanding of frontal polymerization in the presence of heat-absorbing second-phase materials and proposes a potential one-step manufacturing method for precisely patterned polymeric and composite materials without masks, molds, or printers.
AB - Frontal polymerization provides a rapid, economic, and environmentally friendly methodology to manufacture thermoset polymers and composites. Despite its efficiency and reduced environmental impact, the manufacturing method is underutilized due to the limited fundamental understanding of its dynamic control. This work reports the control and patterning of the front propagation in a dicyclopentadiene resin by immersion of phase-changing polycaprolactone particles. Predictive and designed patterning is enabled by multiphysical numerical analyses, which reveal that the interplay between endothermic phase transition, exothermic chemical reaction, and heat exchange govern the temperature, velocity, and propagation path of the front via two different interaction regimes. To pattern the front, one can vary the size and spacing between the particles and increase the number of propagating fronts, resulting in tunable physical patterns formed due to front separation and merging near the particles. Both single- and double-frontal polymerization experiments in an open mold are performed. The results confirm the front–particle interaction mechanisms and the shapes of the patterns explored numerically. The present study offers a fundamental understanding of frontal polymerization in the presence of heat-absorbing second-phase materials and proposes a potential one-step manufacturing method for precisely patterned polymeric and composite materials without masks, molds, or printers.
KW - frontal polymerization
KW - front–particle interaction regime
KW - phase transition
KW - thermal patterning
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U2 - 10.1002/smll.202102217
DO - 10.1002/smll.202102217
M3 - Article
C2 - 34528371
AN - SCOPUS:85114917885
SN - 1613-6810
VL - 17
JO - Small
JF - Small
IS - 42
M1 - 2102217
ER -