Pore Network Tortuosity Controls Fast-Charging in Supercapacitors

24 December 2024, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Ionic transport within porous carbon electrodes is crucial for optimizing charge/discharge rates in supercapacitors, yet the material properties governing ion dynamics remain poorly understood. Contrary to the traditional viewpoint, we find that mesoporosity does not necessarily correlate with high supercapacitor rate capability. Instead, we employed pulsed field gradient nuclear magnetic resonance to directly measure anionic effective diffusivities in the carbon pores, offering a probe of ionic transport in supercapacitors. Our findings reveal a significant discrepancy between short-range and long-range diffusivities, which captures the tortuosity of the pore network. Short-range diffusivities lack correlation with supercapacitor rate capability, whereas long-range diffusivities correlate strongly. Ultimately, low-tortuosity nanoporous carbons exhibited superior rate capability, highlighting the importance of well-interconnected pore networks for efficient ion transport. Our study reveals pore network tortuosity as a key factor that governs charging rates in amorphous nanoporous carbons and guides the design of electrodes with optimized transport channels to enhance supercapacitor performance.

Keywords

Nuclear Magnetic Resonance
Supercapacitors

Supplementary materials

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Figure S1 Supercapacitor rate capability measured across various nanoporous carbons and electrolytes Figure S2 N2 physisorption isotherms and pore size distribution plots Figure S3 Dependence of 19F PFG diffusion coefficient on diffusion time for 1 M TEA-BF4 in acetonitrile. Figure S4 19F NMR spectra of nanoporous carbons soaked in 1M electrolyte Figure S5 19F Diffusion measurements Figure S6 Tortuosity measurement: diffusion coefficients vs diffusion time Figure S7 Correlations between tortuosity and mesoporous SSA with long-range diffusion coefficient
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