A bipolar porphyrin molecule for stable dual-ion symmetric batteries with high potential.

The small molecule 5,15-di(thiophen-2-yl) porphyrin (TP) was developed for new dual-ion symmetric organic batteries (DSOBs). It delivered a capacity of 150 mA h g at 0.2 A g with a high voltage of 2.

A bipolar pyridine-functionalized porphyrin with hybrid charge-storage for dual-ion batteries.

A metal-free porphyrin T4PP with a pyridine group is proposed as a new electrode for lithium/sodium-based dual-ion batteries (LDIBs/SDIBs). The electrochemical performance and reaction mechanism of T4PP are explored thoroughly. The extended porphyrin conjugated structure by the pyridine groups enables an excellent cycle life (5000 cycles) and a high-power density (18.

Long-Term Cycling Stability of Porphyrin Electrode for Li/Na Charge Storage at High Temperature.

Bipolar redox organic compounds have been considered as potential next-generation electrode materials due to their sustainability, low cost and tunable structure. However, their development is still limited by the poor cycling stability and low energy density ascribed to high dissolution during cycling and the low conductivity of organic molecules. Herein, porphyrin-based bipolar organics of [5,10,15,20-tetrathienylporphinato] M (M=2 H, Cu (CuTTP)) are proposed as new stable organic electrodes.