Case ID: M25-305P^

Published: 2026-07-13 19:51:56

Last Updated: 1783972316


Inventor(s)

Wenbo Wang
Xiangfan Chen

Technology categories

Advanced Materials/NanotechnologyManufacturing/Construction/MechanicalMedical DevicesPhysical ScienceWearable

Licensing Contacts

Physical Sciences Team

3D-Printable Graded Electroactive Hydrogels

Invention Description
Electroactive hydrogels (EAHs) change shape in electric fields, making them highly valuable for soft actuators, biomedical and smart devices. However, traditional EAHs struggle with weak mechanics, limited printability, and uniform stiffness. Further, current multi-material alternatives are prone to failure because the joins between different materials easily delaminate or break.
 
Researchers at Arizona State University have designed novel 3D-printable and tunable EAH materials which enable both electroactivity and mechanical resilience. The EAH formulation used is based on acrylic acid (AA), which provides electrical responsiveness and 4-hydroxybutyl acrylate (4-HBA) which enhances mechanical strength and flexibility. A dynamic fluid-assisted micro continuous liquid interface production (DF-μCLIP) process is used for EAH assembly. DF-µCLIP is an innovative stereolithography-based 3D printing technique that overcomes traditional limitations in multi-material printing such as slow material switching and weak interface strength. By utilizing a polymerization-free "dead zone" and synchronized resin replenishment, it achieves continuous, high-resolution printing at speeds up to 90 mm/hour with fine detail of 7.4 µm per pixel. This overcomes interfacial limitations and enables programmable, integrated functionality essential for next-generation soft robotic and biomedical devices.
 
This breakthrough 3D printing method enables the rapid fabrication of electroactive hydrogels combining superior mechanical flexibility and responsive actuation for next-generation soft devices.
 
Potential Applications
  • Soft robotics requiring responsive and durable actuators
  • Wearable electronic devices with adaptive and flexible components
  • Medical/biomedical devices that benefit from tunable mechanical and actuation properties
  • Biosensors incorporating shape-changing hydrogels for enhanced sensitivity
  • Advanced composite manufacturing of custom electroactive components
Benefits and Advantages
  • Enables high speed continuous multi-material printing at 90 mm/hr without gradients
  • Tunable materials allow designers to balance actuation speed, bending curvature, and durability
  • High-resolution (7.4 µm per pixel), continuous 3D printing for smooth, complex structures
  • Tailorable mechanical and electroactive properties through material composition
  • Rapid fabrication reducing production time and cost
  • Enhanced bending curvature and faster response under electric fields
  • Enhanced interfacial mechanical strength with flexible actuation capabilities
  • Able to print continuous compositional gradients rather than step-wise layers
  • Real-time resin replenishment allowing uninterrupted fabrication
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