posted on 2024-11-30, 05:14authored byHanqiang Zhang, Peiren Wang, Heng Zhang, Gangsheng Chen, Kai Wang, Xiaoyi Chen, Zhen Chen, Mingxing Jiang, Junhui Yang, Min Chen, Ji Li
Mechanically robust and electrically
conductive hydrogels hold
significant promise for flexible device applications. However, conventional
fabrication methods such as casting or injection molding meet challenges
in delivering hydrogel objects with complex geometric structures and
multicustomized functionalities. Herein, a 3D printable hydrogel with
excellent mechanical properties and electrical conductivity is implemented
via a facile one-step preparation strategy. With vat polymerization
3D printing technology, the hydrogel can be solidified based on a
hybrid double-network mechanism involving in situ chemical and physical
dual cross-linking. The hydrogel consists of two chemical networks
including covalently cross-linked poly(acrylamide-co-acrylic acid) and chitosan, and zirconium ions are induced to form
physically cross-linked metal-coordination bonds across both chemical
networks. The 3D-printed hydrogel exhibits multiple excellent functionalities
including enhanced mechanical properties (680% stretchability, 15.1
MJ/m3 toughness, and 7.30 MPa tensile strength), rapid
printing speed (0.7–3 s/100 μm), high transparency (91%),
favorable ionic conductivity (0.75 S/m), large strain gauge factor
(≥7), and fast solvent transfer induced phase separation (in
∼3 s), which enable the development of high-performance flexible
wearable sensors, shape memory actuators, and soft pneumatic robotics.
The 3D printable multifunctional hydrogel provides a novel path for
customizing next-generation intelligent soft devices.