Reversible Dual Anionic-Redox Reaction in Layered Chalcogenide Cathode Materials

AbstractLithia-based materials are promising cathodes based on an anionic (oxygen) redox reaction for lithium ion batteries due to their high capacity and stable cyclic performance. In this study, the properties of a lithia-based cathode activated by Li2RuO3 were characterized. Ru-based oxides are expected to act as good catalysts because they can play a role in stabilizing the anion redox reaction. Their high electronic conductivity is also attractive because it can compensate for the low conductivity of lithia. The lithia/Li2RuO3 nanocomposites show stable cyclic performance until a capacity limit of 500 mAh g−1 is reached, which is below the theoretical capacity (897 mAh g−1) but superior to other lithia-based cathodes. In the XPS analysis, while the Ru 3d peaks in the spectra barely changed, peroxo-like (O2)n− species reversibly formed and dissociated during cycling. This clearly confirms that the capacity of the lithia/Li2RuO3 nanocomposites can mostly be attributed to the anionic (oxygen) redox reaction.

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New Insights into Anionic Redox Reaction and Performance Degradation of Iron-Based Layered Oxides Cathode Materials for Sodium-Ion Batteries

ECS Meeting Abstracts ◽

10.1149/ma2018-01/3/494 ◽

2018 ◽

Keyword(s):

Cathode Materials ◽

Redox Reaction ◽

Performance Degradation ◽

Sodium Ion ◽

Sodium Ion Batteries ◽

Layered Oxides ◽

Iron Based ◽

And Performance

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Boron-doped sodium layered oxide for reversible oxygen redox reaction in Na-ion battery cathodes

Nature Communications ◽

10.1038/s41467-021-25610-7 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Yu-Jie Guo ◽

Peng-Fei Wang ◽

Yu-Bin Niu ◽

Xu-Dong Zhang ◽

Qinghao Li ◽

...

Keyword(s):

Cathode Material ◽

High Voltage ◽

Cathode Materials ◽

Redox Reaction ◽

Structural Changes ◽

Active Material ◽

Charge Compensation ◽

High Energy ◽

Structural Instability ◽

Capacity Retention

AbstractNa-ion cathode materials operating at high voltage with a stable cycling behavior are needed to develop future high-energy Na-ion cells. However, the irreversible oxygen redox reaction at the high-voltage region in sodium layered cathode materials generates structural instability and poor capacity retention upon cycling. Here, we report a doping strategy by incorporating light-weight boron into the cathode active material lattice to decrease the irreversible oxygen oxidation at high voltages (i.e., >4.0 V vs. Na+/Na). The presence of covalent B–O bonds and the negative charges of the oxygen atoms ensures a robust ligand framework for the NaLi1/9Ni2/9Fe2/9Mn4/9O2 cathode material while mitigating the excessive oxidation of oxygen for charge compensation and avoiding irreversible structural changes during cell operation. The B-doped cathode material promotes reversible transition metal redox reaction enabling a room-temperature capacity of 160.5 mAh g−1 at 25 mA g−1 and capacity retention of 82.8% after 200 cycles at 250 mA g−1. A 71.28 mAh single-coated lab-scale Na-ion pouch cell comprising a pre-sodiated hard carbon-based anode and B-doped cathode material is also reported as proof of concept.

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Insight into the Redox Reaction Heterogeneity within Secondary Particles of Nickel-Rich Layered Cathode Materials

ACS Applied Materials & Interfaces ◽

10.1021/acsami.1c05819 ◽

2021 ◽

Author(s):

Jiyang Li ◽

Jingxin Huang ◽

Hongyang Li ◽

Xiangbang Kong ◽

Xue Li ◽

...

Keyword(s):

Cathode Materials ◽

Redox Reaction ◽

Secondary Particles ◽

Layered Cathode Materials ◽

Insight Into

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High-performance Na ion cathodes based on the ubiquitous and reversible O redox reaction

Journal of Materials Chemistry A ◽

10.1039/c8ta05961f ◽

2018 ◽

Vol 6 (47) ◽

pp. 24120-24127 ◽

Cited By ~ 2

Author(s):

M. Hussein N. Assadi ◽

Marco Fronzi ◽

Mike Ford ◽

Yasuteru Shigeta

Keyword(s):

High Voltage ◽

Cathode Materials ◽

Redox Reaction ◽

High Performance ◽

High Capacity

We identified high capacity, high voltage and low-strain Na cathode materials that rely on the reversible oxygen redox reaction.

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Lithia/(Ir, Li2IrO3) nanocomposites for new cathode materials based on pure anionic redox reaction

Scientific Reports ◽

10.1038/s41598-019-49806-6 ◽

2019 ◽

Vol 9 (1) ◽

Cited By ~ 2

Author(s):

Si Yeol Lee ◽

Yong Joon Park

Keyword(s):

Cathode Materials ◽

Redox Reaction ◽

Redox Reactions ◽

Milling Process ◽

Pure Oxygen ◽

Cyclic Performance ◽

Reaction Products ◽

New Approach ◽

Step Heat Treatment ◽

Lower Overpotential

Abstract Anionic redox reactions attributed to oxygen have attracted much attention as a new approach to overcoming the energy-density limits of cathode materials. Several oxides have been suggested as new cathode materials with high capacities based on anionic (oxygen) redox reactions. Although most still have a large portion of their capacity based on the cationic redox reaction, lithia-based cathodes present high capacities that are purely dependent upon oxygen redox. Contrary to Li-air batteries, other systems using pure oxygen redox reactions, lithia-based cathodes charge and discharge without a phase transition between gas and condensed forms. This leads to a more stable cyclic performance and lower overpotential compared with those of Li-air systems. However, to activate nanolithia and stabilize reaction products such as Li2O2 during cycling, lithia-based cathodes demand efficient catalysts (dopants). In this study, Ir based materials (Ir and Li2IrO3) were introduced as catalysts (dopants) for nanolithia composites. Oxide types (Li2IrO3) were used as source materials of catalyst because ductile metal (Ir) can hardly be pulverized during the milling process. Two types of Li2IrO3 were prepared and used for catalyst-sources. They were named ‘1-step Li2IrO3’ and ‘2-step Li2IrO3’, respectively, since they were prepared by ‘1-step’ or ‘2-step’ heat treatment. The nanocomposites prepared using lithia & 2-step Li2IrO3 presented a higher capacity, more stable cyclic performance, and lower overpotential than those of the nanocomposites prepared using lithia & 1-step Li2IrO3. The voltage profiles of the nanocomposites prepared using lithia & 2-step Li2IrO3 were stable up to a limited capacity of 600 mAh·g−1, and the capacity was maintained during 100 cycles. XPS analysis confirmed that the capacity of our lithia-based compounds is attributable to the oxygen redox reaction, whereas the cationic redox related to the Ir barely contributes to their discharge capacity.

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Reversible Dual Anionic-Redox Chemistry in NaCrSSe with Fast Charging Capability

10.21203/rs.3.rs-40019/v1 ◽

2020 ◽

Author(s):

Ding-Ren Shi ◽

Zulipiya Shadike ◽

Tian Wang ◽

Si-Yu Yang ◽

He-Yi Xia ◽

...

Keyword(s):

Cathode Materials ◽

Redox Reaction ◽

High Capacity ◽

Charge Compensation ◽

Redox Chemistry ◽

High Energy ◽

High Rate ◽

Structure Evolution ◽

Fast Kinetics ◽

Almost All

Abstract Utilizing the anionic redox reaction opens new approaches for the development of new battery cathode materials with extra capacities. Although, it suffers from several obstacles such as voltage hysteresis and sluggish kinetics. In this paper, a new layered chalcogenide-based on dual anionic-redox reaction is reported. The newly designed layered NaCrSSe exhibits the capacity of almost all Na+ intercalation/deintercalation (137 mAh g-1 at 50 mA g-1), and a unique charge/discharge feature with a small polarization of 0.15 V and high energy efficiencies of ~92% in initial cycles. Furthermore, a superior high-rate charge capacity of 115.5mAh g-1 (83.7% retention) was achieved at 27.8 C (4000 mA g-1), which is impressive in all bulk materials for sodium-ion batteries. Systematic characterization studies on structure evolution and DFT calculation show the charge compensation of S and Se anions during cycling. These results will enrich the anion redox chemistry and provide valuable information for developing new anion redox based cathode materials with high capacity and fast kinetics.

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