Magneto-Orientation of Magnetic Double Stacks for Patterned Anisotropic Hydrogels with Multiple Responses and Modulable Motions

Reported here is a multi-response anisotropic poly(N-isopropylacrylamide) hydrogel developed by using a rotating magnetic field to align magnetic double stacks (MDSs) that are fixed by polymerization. The magneto-orientation of MDSs originates from the unique structure with gamma-Fe2O3 nanoparticles sandwiched by two silicate nanosheets. The resultant gels not only exhibit anisotropic optical and mechanical properties but also show anisotropic responses to temperature and light. Gels with complex ordered structures of MDSs are further devised by multi-step magnetic orientation and photolithographic polymerization. These gels show varied birefringence patterns with potentials as information materials, and can deform into specific configurations upon stimulations. Multi-gait motions are further realized in the patterned gel through dynamic deformation under spatiotemporal light and friction regulation by imposed magnetic force. The magneto-orientation assisted fabrication of hydrogels with anisotropic structures and additional functions should bring opportunities for gel materials in biomedical devices, soft actuators/robots, etc.

Automated summary

A multi-response anisotropic poly(N-isopropylacrylamide) hydrogel was developed using a rotating magnetic field to align magnetic double stacks (MDSs) fixed by polymerization. The gels exhibited anisotropic optical and mechanical properties, as well as anisotropic responses to temperature and light. With further magnetic orientation and photolithographic polymerization, complex ordered structures of MDSs were achieved, allowing the gels to have potential applications as information materials and the ability to deform into specific configurations.