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Protein Crystallization-Mediated Self-Strengthening of High-Performance Printable Conducting Organohydrogels

Jupen Liu, Bo Zhang, Ping Zhang, Keqi Zhao, Zhe Lu, Hongqiu Wei, Zijian Zheng, Rusen Yang, You Yu

2022ACS Nano41 citationsDOI

Abstract

Conductive polymers have many advanced applications, but there is still an important target in developing a general and straightforward strategy for printable, mechanically stable, and durable organohydrogels with typical conducting polymers of, for example, polypyrrole, polyaniline, or poly(3,4-ethylenedioxythiophene). Here we report a protein crystallization-mediated self-strengthening strategy to fabricate printable conducting organohydrogels with the combination of rational photochemistry design. Such organohydrogels are one-step prepared via rapidly and orthogonally controllable photopolymerizations of pyrroles and gelatin protein in tens of seconds. As-prepared conducting organohydrogels are patterned and printed to complicated structures via shadow-mask lithography and 3D extrusion technology. The mild photocatalytic system gives the transition metal carbide/nitride (MXene) component high stability during the oxidative preparation process and storage. Controlling water evaporation promotes gelatin crystallization in the as-prepared organohydrogels that significantly self-strengthens their mechanical property and stability in a broad temperature range and durability against continuous friction treatment without introducing guest functional materials. Also, these organohydrogels have commercially electromagnetic shielding, thermal conducting properties, and temperature- and light-responsibility. To further demonstrate the merits of this simple strategy and as-prepared organohydrogels, prism arrays, as proofs-of-concept, are printed and applied to make wearable triboelectric nanogenerators. This self-strengthening process and 3D-printability can greatly improve their voltage, charge, and current output performances compared to the undried and flat samples.

Topics & Concepts

Materials scienceCrystallizationNanotechnologyTriboelectric effectEvaporationPolyanilineChemical engineeringPolymerComposite materialPolymerizationEngineeringThermodynamicsPhysicsAdvanced Sensor and Energy Harvesting MaterialsConducting polymers and applicationsSupercapacitor Materials and Fabrication
Protein Crystallization-Mediated Self-Strengthening of High-Performance Printable Conducting Organohydrogels | Litcius