Litcius/Paper detail

3D Printing of Porous Nitrogen-Doped Ti<sub>3</sub>C<sub>2</sub> MXene Scaffolds for High-Performance Sodium-Ion Hybrid Capacitors

Zhaodi Fan, Chaohui Wei, Lianghao Yu, Xia Zhou, Jingsheng Cai, Zhengnan Tian, Guifu Zou, Shi Xue Dou, Jingyu Sun

2020ACS Nano293 citationsDOI

Abstract

3D printing technology has stimulated a burgeoning interest to fabricate customized architectures in a facile and scalable manner targeting wide ranged energy storage applications. Nevertheless, 3D-printed hybrid capacitor devices synergizing favorable energy/power density have not yet been explored thus far. Herein, we demonstrate a 3D-printed sodium-ion hybrid capacitor (SIC) based on nitrogen-doped MXene (N-Ti3C2Tx) anode and activated carbon cathode. N-Ti3C2Tx affording a well-defined porous structure and uniform nitrogen doping can be obtained via a sacrificial template method. Thus-formulated ink can be directly printed to form electrode architecture without the request of a conventional current collector. The 3D-printed SICs, with a large areal mass loading up to 15.2 mg cm–2, can harvest an areal energy/power density of 1.18 mWh cm–2/40.15 mW cm–2, outperforming the state-of-the-art 3D-printed energy storage devices. Furthermore, our SIC also achieves a gravimetric energy/power density of 101.6 Wh kg–1/3269 W kg–1. This work demonstrates that the 3D printing technology is versatile enough to construct emerging energy storage systems reconciling high energy and power density.

Topics & Concepts

Materials scienceAnodeEnergy storagePower densityCathodeCapacitorOptoelectronicsNanotechnologySupercapacitorPorosityElectrodeCapacitanceElectrical engineeringPower (physics)Composite materialChemistryVoltageQuantum mechanicsPhysical chemistryEngineeringPhysicsMXene and MAX Phase MaterialsSupercapacitor Materials and FabricationAdvanced Memory and Neural Computing