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Electrochemical activation of oxygen atom of SnO2 to expedite efficient conversion reaction for alkaline-ion (Li+/Na+/K+) storages
Nano Research 2023, 16(1): 1642-1650
Published: 08 November 2022
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SnO2-based anode materials have attracted much attention due to high capacity and relatively mild voltage platforms. However, limited by low initial Coulombic efficiency (ICE) and poor stability, its practical application is still challenging. Recently, it has been found that compositing carbon or metal particles with SnO2 is an effective strategy to achieve high alkaline-ion storages. Although this strategy may improve the kinetics and ICE of the electrochemical reaction, the specific mechanism has not been clearly elucidated. In this work, we found that the invalidation SnO2 may go through two steps: 1) the conversion process from SnO2 to Sn and Li2O; 2) the collapse of the electrode material resulted from huge volume changes during the alloyed Sn with alkaline ions. To address these issues, a unique robust Co-NC shell derived from ZIF-67 is introduced, in which the transited metallic Co nanoparticles could accelerate the decomposition of Sn-O and Li-O bonds, thus expedite the kinetics of conversion reaction. As a result, the SnO2@Co-NC electrode achieves a more complete and efficient transfer between SnO2 and Sn phases, possessing a potential to achieve high alkaline-ion (Li+/Na+/K+) storages.

Research Article Issue
Stabilizing effects of atomic Ti doping on high-voltage high-nickel layered oxide cathode for lithium-ion rechargeable batteries
Nano Research 2022, 15(5): 4091-4099
Published: 18 January 2022
Abstract PDF (3.1 MB) Collect
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High-voltage high-nickel lithium layered oxide cathodes show great application prospects to meet the ever-increasing demand for further improvement of the energy density of rechargeable lithium-ion batteries (LIBs) mainly due to their high output capacity. However, severe bulk structural degradation and undesired electrode–electrolyte interface reactions seriously endanger the cycle life and safety of the battery. Here, 2 mol% Ti atom is used as modified material doping into LiNi0.6Co0.2Mn0.2O2 (NCM) to reform LiNi0.6Co0.2Mn0.18Ti0.02O2 (NCM-Ti) and address the long-standing inherent problem. At a high cut-off voltage of 4.5 V, NCM-Ti delivers a higher capacity retention ratio (91.8% vs. 82.9%) after 150 cycles and a superior rate capacity (118 vs. 105 mAh·g−1) at the high current density of 10 C than the pristine NCM. The designed high-voltage full battery with graphite as anode and NCM-Ti as cathode also exhibits high energy density (240 Wh·kg−1) and excellent electrochemical performance. The superior electrochemical behavior can be attributed to the improved stability of the bulk structure and the electrode–electrolyte interface owing to the strong Ti–O bond and no unpaired electrons. The in-situ X-ray diffraction analysis demonstrates that Ti-doping inhibits the undesired H2-H3 phase transition, minimizing the mechanical degradation. The ex-situ TEM and X-ray photoelectron spectroscopy reveal that Ti-doping suppresses the release of interfacial oxygen, reducing undesired interfacial reactions. This work provides a valuable strategic guideline for the application of high-voltage high-nickel cathodes in LIBs.

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