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Lithiophilic Dibenzamide Linkages to Impart Lithium Storage Capacity in Porous Polybenzamides

Shayan Karak, Himanshi Singh, Arup Biswas, Satyadip Paul, Souvik Manna, Yusuke Nishiyama, Biswarup Pathak, Abhik Banerjee, Rahul Banerjee

2024Journal of the American Chemical Society16 citationsDOI

Abstract

Polymer-based organic cathode materials have shown immense promise for lithium storage, owing to their structural diversity and functional group tunability. However, designing appropriate high-performance cathode materials with a high-rate capability and long cycle life remains a significant challenge. It is quintessential to design polymer-based electrodes with lithiophilic linkages. Herein, we design a bifurcated dibenzamide (DBA) linkage having lithiophilic functionalities. 1 H NMR has been used as an experimental tool to understand the lithiophilic nature of the DBAs. Considering the strong Li + affinity of DBAs, a series of polybenzamides have been designed as lithium storage systems. The design of porous polybenzamides consists of amides as only redox-active functionalities, and the rest are inactive phenyl units. Porous polybenzamides, when tested as cathodes against a Li-metal anode, displayed high capacity and rate performance, demonstrating their redox activity. The most efficient polybenzamide (TAm-TA) delivered a specific capacity of 248 mA h g –1 at 1C. TAm-TA retained 63% of its specific capacity at a very high rate of 10C (157 mA h g –1 ). Notably, polybenzamides displayed a capacity enhancement during long cycling, tending to achieve their theoretical capacity. Long cycling stability tests over 3000 cycles at a rate of 1.3C and over 6000 cycles at elevated rates (5C to 40C) demonstrate the electrochemical robustness of dibenzamide linkages. Finally, two full-cell experiments using TAm-TA as both cathode and anode were conducted, which delivered high capacity, demonstrating that TAm-TA is a promising candidate for Li + -ion batteries (LIBs). Furthermore, the ex situ Fourier transform infrared (FT-IR), X-ray photoemission spectroscopy (XPS), and density functional theory (DFT) studies revealed the stepwise lithiation/delithiation mechanism for polybenzamides.

Topics & Concepts

ChemistryLithium (medication)PorosityChemical engineeringOrganic chemistryInternal medicineMedicineEngineeringCovalent Organic Framework ApplicationsConducting polymers and applicationsAdvanced Battery Materials and Technologies
Lithiophilic Dibenzamide Linkages to Impart Lithium Storage Capacity in Porous Polybenzamides | Litcius