Nitrogen-doped graphene based triboelectric nanogenerators

TL;DR

This paper demonstrates that nitrogen-doped graphene electrodes significantly enhance the power output of triboelectric nanogenerators by optimizing doping types and interface placement, offering a promising route for sustainable energy harvesting.

Contribution

It introduces nitrogen-doped graphene as an electrode material in TENGs, showing how doping type and interface placement affect performance, which was not previously explored.

Findings

N-doped graphene increases TENG power output threefold.

Performance depends on doping concentration and N-site content.

Optimal interface placement enhances energy harvesting efficiency.

Abstract

Harvesting all sources of available clean energy is an essential strategy to contribute to healing current dependence on non-sustainable energy sources. Recently, triboelectric nanogenerators (TENGs) have gained visibility as new mechanical energy harvester offering a valid alternative to batteries, being particularly suitable for portable devices. Here, the increased capacitance of a few-layer graphene-based electrode is obtained by incorporating nitrogen-doped graphene (N_graphene), enabling a 3_fold enhancement in TENGs power output. The dependence of TENGs performance on the electronic properties of different N_graphene types, varying in the doping concentration and in the relative content of N-pyridinic and N-graphitic sites is investigated. These sites have different electron affinities, and synergistically contribute to the variation of the capacitive and resistive properties of N-graphene and consequently, TENG performance. It is demonstrated that the power enhancement of the TENG occurs when the N_graphene, an n-semiconductor, is interfaced between the positive triboelectric material and the electrode, while a deterioration of the electrical performance is observed when it is placed at the interface with the negative triboelectric material. This behavior is explained in terms of the dependence of N_graphene quantum capacitance on the electrode chemical potential which shifts according to the opposite polarization induced at the two electrodes upon triboelectrification.