What question did this study set out to answer?

The aim is to improve the reversibility of Li–O2 batteries by enhancing reaction pathways and reducing charge polarization.

March 18, 2026

In Situ PrO x Framework Enables Reversible Reaction Pathways in Li–O 2 Batteries

Key Points

The aim is to improve the reversibility of Li–O2 batteries by enhancing reaction pathways and reducing charge polarization.
Introduced Pr(NO3)3 as an electrolyte additive.
Generated an amorphous PrOx framework on Co3O4/CNT cathode.
Monitored changes in charge potential and voltage gaps during battery cycling.
Voltage gap decreased from 1.66 to 1.16 V at 200 μA cm–2.
Limited capacity achieved at 400 μAh cm–2.
Suppressed formation of Li2CO3 and improved cycling stability.

Abstract

The practical reversibility of Li–O2 batteries is constrained by the electronically insulating discharge product Li2O2, which limits interfacial reaction kinetics, induces large charge polarization, and accelerates electrolyte decomposition. Here we introduce Pr(NO3)3 as an electrolyte additive to generate in situ an amorphous, three-dimensional PrOx framework on a Co3O4/CNT cathode during the first discharge. This framework confines Li2O2 growth to produce nanosized, poorly ordered Li2O2 and, at the same time, provides abundant active sites and continuous electron pathways for O2 redox and Li2O2 formation/decomposition. As a result, the voltage gap decreases from 1.66 to 1.16 V at 200 μA cm–2 under a limited capacity of 400 μAh cm–2. The lowered charging potential also suppresses Li2CO3 formation, leading to an improved cycling stability.

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In Situ PrO x Framework Enables Reversible Reaction Pathways in Li–O 2 Batteries

Key Points

Abstract

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