A “Trinity” Design of Li‐O2 Battery Engaging the Slow‐Release Capsule of Redox Mediators

Nonaqueous Li‐O2 battery (LOB) represents one of the promising next‐gen energy storage solutions owing to its ultrahigh energy density but suffers from problems such as high charging overpotential, slow redox kinetics, Li anode corrosion, etc., calling for a systemic optimization of the battery conf...

Full description

Saved in:
Bibliographic Details
Published in:Advanced materials (Weinheim) 2023-12, Vol.35 (49), p.e2308134-n/a
Main Authors: He, Ying, Ding, Leyu, Cheng, Jian, Mei, Shiwei, Xie, Xulan, Zheng, Zhangyi, Pan, Weiyi, Qin, Yongze, Huang, Fangding, Peng, Yang, Deng, Zhao
Format: Article
Language:English
Subjects:
Anodic protection
Cathodes
Cathodic protection
Corrosion rate
Discharge
Electrode polarization
Energy storage
lithium anode protection
lithium‐oxygen batteries
Mass transport
Metal-organic frameworks
oxygen catalyst
Polypyrroles
Reaction kinetics
redox mediators
Smart materials
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Nonaqueous Li‐O2 battery (LOB) represents one of the promising next‐gen energy storage solutions owing to its ultrahigh energy density but suffers from problems such as high charging overpotential, slow redox kinetics, Li anode corrosion, etc., calling for a systemic optimization of the battery configuration and structural components. Herein, an ingenious “trinity” design of LOB is initiated by implementing a hollowed cobalt metal organic framework (MOF) impregnating iodized polypyrrole simultaneously as the cathode catalyst, anode protection layer, and slow‐release capsule of redox mediators, so as to systemically address issues of impeded mass transport and redox kinetics on the cathode, dendrite growth, and surface corrosion on the anode, as well as limited intermediate solubility in the low donor‐number (DN) solvent. As a result of the systemic effort, the LOB constructed demonstrates an ultralow discharge/charge polarization of 0.2 V, prolonged cycle life of 1244 h and total discharge capacity of 28.41 mAh cm−2. Mechanistic investigations attribute the superb LOB performance to the redox‐mediated solution growth mechanism of crystalline Li2O2 with both enhanced reaction kinetics and reversibility. This study offers a paradigm in designing smart materials to raise the performance bar of Li‐O2 battery toward realistic applications. A smart “trinity” design of Li‐O2 battery is initiated by employing hollow cobalt metal organic frameworks impregnating iodized polypyrrole simultaneously for cathode catalyst, anode protection, and slow‐release redox mediators (RM). Mechanistic investigations assert the critical role of RM‐mediated solution growth of crystalline Li2O2 to greatly boost both the capacity and cycling reversibility.
ISSN:0935-9648
1521-4095
DOI:10.1002/adma.202308134