Demystifying the Lattice Oxygen Redox in Layered Oxide Cathode Materials of Lithium-Ion Batteries

Chen, Jun; Deng, Wentao; Gao, Xu; Yin, Shouyi; Yang, Li; Liu, Huanqing; Zou, Guoqiang; Hou, Hongshuai; Ji, Xiaobo

doi:10.1021/acsnano.1c00304

Cited by 92 publications

(51 citation statements)

References 367 publications

(728 reference statements)

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“…[1][2][3][4][5] However, these oxides suffer from a big challenge of voltage decay, which is closely related to the issues of irreversible transition metal (TM) cation migration [6] and lattice oxygen escape. [7,8] It is generally accepted that the voltage fade is primarily rooted in the accumulation of irreversible cation migration. A comprehensive investigation of the Li-rich Mn-based oxide with an exacerbate voltage decline declares that an increasing amount of TM cations are indeed trapped into the Li layers.…”

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confidence: 99%

Facilitating Reversible Cation Migration and Suppressing O₂ Escape for High Performance Li‐Rich Oxide Cathodes

Chai

Zhang

et al. 2022

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High‐capacity Li‐rich Mn‐based oxide cathodes show a great potential in next generation Li‐ion batteries but suffer from some critical issues, such as, lattice oxygen escape, irreversible transition metal (TM) cation migration, and voltage decay. Herein, a comprehensive structural modulation in the bulk and surface of Li‐rich cathodes is proposed through simultaneously introducing oxygen vacancies and P doping to mitigate these issues, and the improvement mechanism is revealed. First, oxygen vacancies and P doping elongates OO distance, which lowers the energy barrier and enhances the reversible cation migration. Second, reversible cation migration elevates the discharge voltage, inhibits voltage decay and lattice oxygen escape by increasing the Li vacancy‐TM antisite at charge, and decreasing the trapped cations at discharge. Third, oxygen vacancies vary the lattice arrangement on the surface from a layered lattice to a spinel phase, which deactivates oxygen redox and restrains oxygen gas (O2) escape. Fourth, P doping enhances the covalency between cations and anions and elevates lattice stability in bulk. The modulated Li‐rich cathode exhibits a high‐rate capability, a good cycling stability, a restrained voltage decay, and an elevated working voltage. This study presents insights into regulating oxygen redox by facilitating reversible cation migration and suppressing O2 escape.

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Facilitating Reversible Cation Migration and Suppressing O₂ Escape for High Performance Li‐Rich Oxide Cathodes

Chai

Zhang

et al. 2022

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“…[76] When the electron are extracted from the overlap region, the ion radius and electrostatic reaction simultaneously reduce, leading to O 2− oxidation, Co dissolution and oxygen loss at high potential. [77,78] Accordingly, continuous O loss during high voltage cycle will result in irreversible phase transitions (CoO 2 →Co 3 O 4 , Figure 5b). [58,79] The generated Co 3 O 4 impedes Li + transport, giving a sharp increase to impedance and capacity decay.…”

Section: Lattice Oxygen Lossmentioning

confidence: 99%

Advancing to 4.6 V Review and Prospect in Developing High‐Energy‐Density LiCoO₂ Cathode for Lithium‐Ion Batteries

Zhang

Guo

et al. 2022

Small Methods

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Layered LiCoO2 (LCO) is one of the most important cathodes for portable electronic products at present and in the foreseeable future. It becomes a continuous push to increase the cutoff voltage of LCO so that a higher capacity can be achieved, for example, a capacity of 220 mAh g–1 at 4.6 V compared to 175 mAh g–1 at 4.45 V, which is unfortunately accompanied by severe capacity degradation due to the much‐aggravated side reactions and irreversible phase transitions. Accordingly, strict control on the LCO becomes essential to combat the inherent instability related to the high voltage challenge for their future applications. This review begins with a discussion on the relationship between the crystal structures and electrochemical properties of LCO as well as the failure mechanisms at 4.6 V. Then, recent advances in control strategies for 4.6 V LCO are summarized with focus on both bulk structure and surface properties. One closes this review by presenting the outlook for future efforts on LCO‐based lithium ion batteries (LIBs). It is hoped that this work can draw a clear map on the research status of 4.6 V LCO, and also shed light on the future directions of materials design for high energy LIBs.

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“…However, demand for the higher capacity urges to operate the battery at higher potential causes the regulation of lattice oxygen redox to become significant along with the transition metal redox for the realization of enhanced electrochemical performance. [ 58 ] Actually, at a higher positive voltage, there is a significant overlapping of 3d and 2p states of the transition metal and oxygen respectively that makes the oxygen redox active. So, in order to analyze redox activity related to Ni and O, X‐ray absorption spectroscopy, resonant inelastic X‐ray scattering, operando Raman spectroscopy, and operando differential electrochemical mass spectroscopy can be used.…”

Section: Structure Of Ni‐rich Layered Oxides and Characterizationmentioning

confidence: 99%

Recent Advances in Enhanced Performance of Ni‐Rich Cathode Materials for Li‐Ion Batteries: A Review

et al. 2022

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High energy Li‐ion batteries (LIBs) have garnered substantial consideration in recent years for their utilization in many fields like communication, transportation, and aviation. As the cathode is the crucial component of LIBs, so by enhancing its electrochemical performance, the capacity, rate capability, as well as cyclability of batteries can be enhanced. Ni‐rich cathode materials (LiNi x Mn y Co1−x−y O2, x ≥ 0.5) have been accredited for their benefits in enhanced capacity, high working voltage, and low manufacturing cost. The high Ni content is accountable for the exceptional capacity but the utilization in the commercialized LIBs is mired by their electrochemical cycling issues like capacity fading, voltage decay, and safety hazard. To overcome these obstructions, a variety of methodologies have been adopted like doping, coating, and comodification of these cathode materials. An inclusive study of Ni‐rich cathode materials, their degradation mechanism, and the strategies is conferred, which have been employed in recent years to overcome the challenges faced by these materials in their commercialization.

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Demystifying the Lattice Oxygen Redox in Layered Oxide Cathode Materials of Lithium-Ion Batteries

Cited by 92 publications

References 367 publications

Facilitating Reversible Cation Migration and Suppressing O₂ Escape for High Performance Li‐Rich Oxide Cathodes

Facilitating Reversible Cation Migration and Suppressing O₂ Escape for High Performance Li‐Rich Oxide Cathodes

Advancing to 4.6 V Review and Prospect in Developing High‐Energy‐Density LiCoO₂ Cathode for Lithium‐Ion Batteries

Recent Advances in Enhanced Performance of Ni‐Rich Cathode Materials for Li‐Ion Batteries: A Review

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Demystifying the Lattice Oxygen Redox in Layered Oxide Cathode Materials of Lithium-Ion Batteries

Cited by 92 publications

References 367 publications

Facilitating Reversible Cation Migration and Suppressing O2 Escape for High Performance Li‐Rich Oxide Cathodes

Facilitating Reversible Cation Migration and Suppressing O2 Escape for High Performance Li‐Rich Oxide Cathodes

Advancing to 4.6 V Review and Prospect in Developing High‐Energy‐Density LiCoO2 Cathode for Lithium‐Ion Batteries

Recent Advances in Enhanced Performance of Ni‐Rich Cathode Materials for Li‐Ion Batteries: A Review

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Facilitating Reversible Cation Migration and Suppressing O₂ Escape for High Performance Li‐Rich Oxide Cathodes

Facilitating Reversible Cation Migration and Suppressing O₂ Escape for High Performance Li‐Rich Oxide Cathodes

Advancing to 4.6 V Review and Prospect in Developing High‐Energy‐Density LiCoO₂ Cathode for Lithium‐Ion Batteries