posted on 2020-11-10, 20:14authored byChen Fei Dai, Xin Ning Zhang, Cong Du, Andreas Frank, Hans-Werner Schmidt, Qiang Zheng, Zi Liang Wu
Gradient
materials exist widely in natural living organisms, affording fascinating
biological and mechanical properties. However, the synthetic gradient
hydrogels are usually mechanically weak or only have relatively simple
gradient structures. Here, we report on tough nanocomposite hydrogels
with designable gradient network structure and mechanical properties
by a facile post-photoregulation strategy. Poly(1-vinylimidazole-co-methacrylic acid) hydrogels containing gold nanorods
(AuNRs) are in a glassy state and show typical yielding and forced
elastic deformation at room temperature. The gel slightly contracts
its volume when the temperature is above the glass-transition temperature
that results in a collapse of the chain segments and formation of
denser intra- and interchain hydrogen bonds. Consequently, the mechanical
properties of the gels are enhanced, when the temperature returns
to room temperature. The mechanical performances of hydrogels can
also be locally tuned by near-infrared light irradiation due to the
photothermal effect of AuNRs. Hydrogels with arbitrary two-dimensional
gradients can be facilely developed by site-specific photoirradiation.
The treated and untreated regions with different stiffness and yielding
stress possess construct behaviors in stretching or twisting deformations.
A locally reinforced hydrogel with the kirigami structure becomes
notch-insensitive and exhibits improved strength and stretchability
because the treated regions ahead the cuts have better resistance
to crack advancement. These tough hydrogels with programmable gradient
structure and mechanics should find applications as structural elements,
biological devices, etc.