Operando Fluorescence Detection of Singlet Oxygen inside High- Performance Li−O2 Batteries

Abstract

It has been established that the Li-O2 battery with the highest energy density, comparable to fossil fuels, undergoes parasitic reactions with degradation of electrolyte and cathode material, which limits the number of cycles due to the formation of very reactive singlet oxygen because of superoxide disproportionation. We present herein for the first time the detection of singlet oxygen inside the battery during the discharge of an aprotic Li-O2 battery in operando by means of a bifurcated optical fiber. The identification of singlet oxygen, 1O2, is based on its reactivity toward the fluorescent probe 9,10-dimethylanthracene (DMA) which is added to the electrolyte rapidly and selectively traps 1O2 by forming its non-fluorescent endoperoxide (DMA-O2) and can be detected in operando following DMA fluorescence decay. Furthermore and as a proof of concept, addition of azide ions, a well-known specific physical quencher of singlet oxygen, improved Li-O2 battery discharge-charge cycling performance at 125-250 mA/g current densities. The new in-operando method is well suited to test new strategies in high-performance Li-O2 batteries.