Highly Durable Ti-Mesh Based Triboelectric Nanogenerator for Self-Powered Device Applications.

We describe a highly durable Ti-mesh based triboelectric nanogenerator (Ti-TENG) with a sandwich structure that harvests electrical energy from contact electrification. The electrical output from the fabricated Ti-TENG by compressing and releasing strain was measured under different applied loads and frequencies. The Ti-TENG generated a peak voltage and current up to -1.1 V and -14 nA at an applied force of 30 N and frequency of 1.1 Hz. Obtained potentials were used to charge a capacitor and power a commercially available light emitting diode (LED). In particular, the Ti-TENG, which exhibited high electrical stability, can be used in applications requiring high levels of robustness and durability. For example, the Ti-TENG was applied as step counter while walking and running, demonstrating its capability to self-power devices. We believe that the device provides a highly promising, robust and durable platform for self-powered applications that effectively harnesses energy from mechanical movements.

Preparation of ZnO Nanorod/Graphene/ZnO Nanorod Epitaxial Double Heterostructure for Piezoelectrical Nanogenerator by Using Preheating Hydrothermal.

Well-aligned ZnO nanostructures have been intensively studied over the last decade for remarkable physical properties and enormous applications. Here, we describe a one-step fabrication technique to synthesis freestanding ZnO nanorod/graphene/ZnO nanorod double heterostructure. The preparation of the double heterostructure is performed by using thermal chemical vapor deposition (CVD) and preheating hydrothermal technique. In addition, the morphological properties were characterized by using the scanning electron microscopy (SEM). The utility of freestanding double heterostructure is demonstrated by fabricating the piezoelectric nanogenerator. The electrical output is improved up to 200% compared to that of a single heterostructure owing to the coupling effect of the piezoelectricity between the arrays of ZnO nanorods on the top and bottom of graphene. This unique double heterostructure have a tremendous potential for applications of electrical and optoelectrical devices where the high number density and specific surface area of nanorod are needed, such as pressure sensor, immuno-biosensor and dye-sensitized solar cells.