Rigid-Rod Sulfonated Polyamide as an Aqueous-Processable Binder for Li-Ion Battery Electrodes

Polymer binders are important components of most battery electrodes, ensuring high performance and long-term durability. Increasing demand for lithium-ion batteries in the automotive, stationary power, and portable electronics industries calls for a greener binder to replace poly(vinylidene difluoride) (PVDF). We evaluate the performance of aqueous solution-processed electrodes prepared with a rigid-rod polymer binder, poly(2,2'-disulfonyl-4,4'-benzidine terephthalamide) (PBDT). The polyamide backbone and double-helical configuration of PBDT give rise to its mechanical strength and rigidity, and its functional nature (H-bonding amides and sulfonates) can provide specific binding with electrode particles. LiFePO4 electrodes prepared with 3 wt % PBDT show mechanical integrity and cycling stability, achieving over 1000 cycles at 4C rate with negligible capacity decay. These electrodes demonstrate comparable rate performance with their PVDF counterparts while eliminating fluorine from the electrode as well as the organic solvents needed for processing. This study reveals that PBDT holds great potential as a binder for advanced sustainable batteries.

Automated summary

Polymer binders play a crucial role in battery electrodes, and a study has found that a rigid-rod polymer binder called PBDT can provide comparable performance to the traditional binder PVDF. Moreover, PBDT has the potential to eliminate fluorine from the electrode and reduce the need for organic solvents in processing, making it a sustainable option for advanced batteries.