Synergistic Catalysis by Single‐Atom Catalysts and Redox Mediator to Improve Lithium–Oxygen Batteries Performance

Abstract: to low round-trip efficiency as well as limited capacity. And cathode clogging arising from insulated, insoluble discharge products accumulation blocks the electron transfer and oxygen/Li + diffusion, resulting in a high overpotential for the electrochemical reactions, which will trigger parasitic reactions such as electrolyte oxidation. [5] As cathode corrosion aggravates, the batteries deliver poor cycle stability.Over the past few decades, numerous studies have intensively focused on cathodes and catalysts … Show more

“…Qiu et al [115] discovered the influence of the dimensionality of the graphene matrix on the formation of Fe SACs [Figure 5]. They revealed that single-shell hollow graphene spheres play a critical role in the preparation of single Fe atom catalysts.…”

Hollow microstructural regulation of single-atom catalysts for optimized electrocatalytic performance

“…Qiu et al [115] discovered the influence of the dimensionality of the graphene matrix on the formation of Fe SACs [Figure 5]. They revealed that single-shell hollow graphene spheres play a critical role in the preparation of single Fe atom catalysts.…”

Hollow microstructural regulation of single-atom catalysts for optimized electrocatalytic performance

“…Lithium peroxide is an insulator with a wide band gap, and its conductivity is poor, which leads to the inability of electrons to be transmitted timely, causing large polarization of the battery. In addition, Li 2 O 2 and the reaction intermediate LiO 2 both have high reactivity and are prone to react with the electrolyte to generate side reaction products, resulting in a decrease in the cycle life of the battery. − It will be of great significance to develop non-Li 2 O 2 -based LOBs. Besides Li 2 O 2 , LiOH, LiO 2 , and even Li 2 O are also other reported reversible discharge products that are obtained by controlling catalysts and optimizing electrolyte systems. , Inspired by these works, we utilized the synergistic effect on the Co 3 O 4 (111) plane to enhance the electrochemical performance of LOBs in water-added electrolytes.…”

Water-Induced Surface Reconstruction of Co₃O₄ on the (111) Plane for High-Efficiency Li–O₂ Batteries in a Hybrid Electrolyte

“…However, the development of LOBs is still hindered by several challenges, such as the limited cycle life, low discharge specific capacity, and poor rate performance, which are mainly due to the sluggish kinetics of the oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) at the oxygen cathodes [4–6] . Therein, Li + reacts with the oxygen to form the eventual Li 2 O 2 product during the discharging process, which decomposes to the Li + and oxygen in the subsequent charging process [7–11] . The major discharge product Li 2 O 2 , which is intrinsically insulating and insoluble in the electrolyte, is deposited on the cathode surface and further causes the degradation of the LOBs [12–15] .…”

“…[4][5][6] Therein, Li + reacts with the oxygen to form the eventual Li 2 O 2 product during the discharging process, which decomposes to the Li + and oxygen in the subsequent charging process. [7][8][9][10][11] The major discharge product Li 2 O 2 , which is intrinsically insulating and insoluble in the electrolyte, is deposited on the cathode surface and further causes the degradation of the LOBs. [12][13][14][15] To data, although some precious metals along with their oxides (Pt, Ru, IrO 2 , RuO 2 ) have shown excellent ORR and OER performance, they cannot be produced in a large scale due to the high cost and low reserve.…”

Engineering Metal Alloy Nanocrystals Anchored on N‐Doped Nanoporous Carbon for Li‐O₂ Batteries