A soft syntactic foam actuator with high recovery stress, actuation strain, and energy output

Novel syntactic foams were prepared by incorporating three types of glass microbubbles in a crosslinked cis poly (1,4-butadiene) (cPBD) matrix. The as-prepared semi-crystalline polymer-based syntactic foams displayed a clear two-way shape memory effect (2W-SME) with remarkable strain actuation of about 56% expansion when the temperature drops from 60 degrees C to 40 degrees C, and about 40% contraction when the temperature rises from -40 degrees C to 60 degrees C, comparable to most pure two-way shape memory polymers. Compared to the pure cPBD, which was actuated under 0.32 MPa tensile stress, the foams were actuated under a much larger external tensile stress of up to 1.6 MPa, signifying its superior actuation capability. The energy output is also much higher for the syntactic foam, up to 0.83 MJ/m(3), compared to 0.28 MJ/m(3) for the pure cPBD. Furthermore, it has a working temperature below zero Celsius and may be actuated at temperatures lower than most other available shape memory polymer foams. With a low density, decent mechanical properties, and great actuation capability, these syntactic foams can be adopted for applications such as artificial muscles, biomedical devices, soft robots, sealants, and aerospace structures, which can be potentially manufactured by 3D printing.

Automated summary

Novel syntactic foams with shape memory effect were prepared by incorporating glass microbubbles into a crosslinked polymer matrix. These foams exhibited remarkable strain actuation and had superior actuation capability compared to pure polymers. With a low density and decent mechanical properties, they are potential candidates for various applications including artificial muscles and biomedical devices.