Fabrication of graphene coated carbon fiber microelectrode for highly sensitive detection application.

Graphene, as a novel carbon nanomaterial, exhibits superior performance in electrochemical sensors. Here, graphene was applied to the microelectrode system by a simple method. A novel graphene coating carbon fiber microelectrode (G-CFM) was fabricated by electrodepositing graphene on the surface of carbon fiber.

An all-cotton-derived, arbitrarily foldable, high-rate, electrochemical supercapacitor.

The pure natural cotton provides a low-cost material platform for the facile assembly of all-cotton-derived electrochemical supercapacitors (allC-ECs) with a remarkable character of arbitrary foldability and high response rate, which can be bent, rolled-up, and fully folded without loss of high-rate (<50 ms) capacitive performance.

Large-scale spinning assembly of neat, morphology-defined, graphene-based hollow fibers.

Large-scale assembly of graphenes in a well-controlled macroscopic fashion is important for practical applications. We have developed a facile and straightforward approach for continuous fabrication of neat, morphology-defined, graphene-based hollow fibers (HFs) via a coaxial two-capillary spinning strategy. With a high throughput, HFs and necklace-like HFs of graphene oxide have been well-controlled produced with the ease of functionalization and conversion to graphene HFs via simply thermal or chemical reduction.