Mechanically Induced Nanoscale Architecture Endows a Titanium Carbide MXene Electrode with Integrated High Areal and Volumetric Capacitance

Complete utilization of electrochemically active materials while maintaining the high areal/volumetric packing density is a goal to be achieved in miniaturized supercapacitor devices, which therefore display both high volumetric and areal energy density. Although critical, it is usually challenging...

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Bibliographic Details
Published in:Advanced materials (Weinheim) 2022-10, Vol.34 (43), p.e2205723-n/a
Main Authors: Chen, Hongwu, Wang, Huaipeng, Li, Chun
Format: Article
Language:English
Subjects:
Capacitance
Diffusion
Display devices
Electrodes
Electrolytes
Energy storage
Interlayers
mechanical compression
Micrometers
MXenes
Packing density
Porosity
powder materials
structural stability
supercapacitors
Titanium carbide
titanium carbide MXene
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Summary:Complete utilization of electrochemically active materials while maintaining the high areal/volumetric packing density is a goal to be achieved in miniaturized supercapacitor devices, which therefore display both high volumetric and areal energy density. Although critical, it is usually challenging to achieve this goal by optimizing the electrode architecture. Dense packing of active materials maximizes the volumetric capacitance but also results in sluggish diffusion of the electrolyte. Structurization of the electrode by forming large pores creates a pathway for electrolyte penetration but reduces the volumetric energy density. Here, densified electrodes with hierarchical porous architecture at the nanoscale are reported, which provide an alternative solution. Worm‐like expanded titanium carbide MXene powders are produced in highly viscous reaction media and assembled by mechanical compression. The expanded morphology of the MXene powders translates into a buckling microstructure in the electrodes, resulting in 28.2 ± 4.1% porosity mainly in the form of nanosized pores. At the sub‐nanometer scale, the diffusion of electrolytes is enhanced in interlayer space of the bended lattice with pillared intercalants. These hierarchical structural features lead to both high areal and volumetric capacitance (11.4 F cm−2 coupled with 770 F cm−3) in hundred‐micrometers‐thick electrodes, which inspires the design of high‐performance electrochemical energy storage devices. Worm‐like expanded titanium carbide MXene powders are synthesized in highly viscous reaction media and form binder‐free densely packed electrodes under mechanical compression of 300 MPa. Buckling of the MXene stacks and intrinsic intercalation structure translate to the hierarchical architecture at the nanoscale which brings excellent performance in both areal and volumetric capacitances.
ISSN:0935-9648
1521-4095
DOI:10.1002/adma.202205723