Litcius/Paper detail

Heavy Atom-Induced Spin–Orbit Coupling to Quench Singlet Oxygen in a Li–O<sub>2</sub> Battery

Zhuoliang Jiang, Bo Wen, Yaohui Huang, Yuzhe Wang, Hengyi Fang, Fujun Li

2025Journal of the American Chemical Society18 citationsDOI

Abstract

Li–O 2 batteries have aroused considerable interest due to high theoretical energy density; however, the singlet oxygen ( 1 O 2 ) generated in both discharge and charge processes induces severe parasitic reactions and leads to their low round-trip efficiency and poor rechargeability. Herein, a universal heavy atom-induced quenching mechanism is proposed to suppress 1 O 2 and related side reactions. Br in tris(4-bromophenyl)amine (TBPA) induces strong heavy atom-induced spin–orbit coupling (SOC), enhancing the interaction between the spin angular momentum and the orbital angular momentum of the electron. It enables TBPA to capture electrophilic 1 O 2 to form a singlet complex and then effectively drives the spin-forbidden spin-flip process to form a triplet complex. This accelerates the conversion of 1 O 2 to ground-state 3 O 2 through a heavy atom-induced intersystem crossing mechanism, and it efficiently eliminates its attack on organic solvents and carbon cathodes. These endow the Li–O 2 battery with reduced overvoltages and prolonged lifespan for over 350 cycles when coupled with a RuO 2 catalyst. This work highlights the heavy atom-induced SOC to quench 1 O 2 in oxygen evolution reaction-related devices.

Topics & Concepts

ChemistrySinglet stateCoupling (piping)Singlet oxygenAtom (system on chip)Atomic physicsSpin–orbit interactionOxygenOxygen atomSpin (aerodynamics)Battery (electricity)Chemical physicsCondensed matter physicsMoleculeExcited stateThermodynamicsPhysicsMetallurgyPower (physics)Embedded systemMaterials scienceOrganic chemistryComputer scienceAdvanced Battery Materials and TechnologiesAdvancements in Battery MaterialsAdvanced Photocatalysis Techniques