Integration of Stiff Graphene and Tough Silk for the Design and Fabrication of Versatile Electronic Materials

• Published in: Advanced functional materials Vol. 28; no. 9
• Main Authors: Ling, Shengjie, Wang, Qi, Zhang, Dong, Zhang, Yingying, Mu, Xuan, Kaplan, David L., Buehler, Markus J.
• Format: Journal Article
• Language: English
• Published: Germany Wiley Subscription Services, Inc 28.02.2018
• Subjects: Deformation resistance; Design optimization; Electronic materials; Graphene; Hydrophobicity; Materials science; Mechanical properties; Nanocomposites; processing; silk; Silk fibroin; Smart materials; Smart sensors; Stiffness; Strain; Suspension systems; Textiles; silk; processing; electronic materials; Graphene
• ISSN: 1616-301X; 1616-3028
• DOI: 10.1002/adfm.201705291

The production of structural and functional materials with enhanced mechanical properties through the integration of soft and hard components is a common approach to Nature's material design. However, directly mimicking these optimized design routes in the lab for practical applications remains challenging. For example, graphene and silk are two materials with complementary mechanical properties that feature ultrahigh stiffness and toughness, respectively. Yet, no simple and controllable approach is developed to homogeneously integrate these two components into functional composites, mainly due to the hydrophobicity and chemical inertness of graphene. In this study, well‐dispersed and highly stable graphene/silk fibroin (SF) suspension systems are developed, which are suitable for processing to fabricate polymorphic materials, such as films, fibers, and coatings. The obtained graphene/SF nanocomposites maintain the electronic advantages of graphene, and they also allow tailorable mechanical performance to form including ultrahigh stretchable (with a strain to failure to 611 ± 85%), or high strength (339 MPa) and high stiffness (7.4 GPa) material systems. More remarkably, the electrical resistances of these graphene/SF materials are sensitive to material deformation, body movement, as well as humidity and chemical environmental changes. These unique features promise their utility as wearable sensors, smart textiles, intelligent skins, and human–machine interfaces. Integration of stiff graphene and tough silk for design and fabrication of mechanically enhanced and electrically conductive materials with polymorphic architectures and versatile functions is reported here.