A novel
and facile assembly strategy has been successfully developed to construct
smart nanocomposite (NC) hydrogels with inhomogeneous structures using
nanoclay-cross-linked stimuli-responsive hydrogel subunits as building
blocks via rearranged hydrogen bonding between polymers and clay nanosheets.
The assembled thermoresponsive poly(N-isopropylacrylamide-co-acrylamide) (poly(NIPAM-co-AM)) hydrogels
with various inhomogeneous structures exhibit excellent mechanical
properties due to plenty of new hydrogen bonding interactions created
at the interface for locking the NC hydrogel subunits, which are strong
enough to tolerate external forces such as high levels of elongations
and multicycles of swelling/deswelling operations. The proposed approach
is featured with flexibility and designability to build assembled
hydrogels with diverse architectures for achieving various responsive
deformations, which are highly promising for stimuli-responsive manipulation
such as actuation, encapsulation, and cargo transportation. Our assembly
strategy creates new opportunities for further developing mechanically
strong hydrogel systems with complex architectures that composed of
diverse internal structures, multistimuli-responsive properties, and
controllable shape deformation behaviors in the soft robots and actuators
fields.