Yan Zhao's research works | Dezhou University and other places

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Construction of Uniform LiF Coating Layers for Stable High-Voltage LiCoO2 Cathodes in Lithium-Ion Batteries

March 2024

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Molecules

[...]

Stabilizing LiCoO2 (LCO) at 4.5 V rather than the common 4.2 V is important for the high specific capacity. In this study, we developed a simple and efficient way to improve the stability of LiCoO2 at high voltages. After a simple sol–gel method, we introduced trifluoroacetic acid (TA) to the surface of LCO via an afterwards calcination. Meanwhile, the TA reacted with residual lithium on the surface of LCO, further leading to the formation of uniform LiF nanoshells. The LiF nanoshells could effectively restrict the interfacial side reaction, hinder the transition metal dissolution and thus achieve a stable cathode–electrolyte interface at high working-voltages. As a result, the LCO@LiF demonstrated a much superior cycling stability with a capacity retention ratio of 83.54% after 100 cycles compared with the bare ones (43.3% for capacity retention), as well as high rate performances. Notably, LiF coating layers endow LCO with excellent high-temperature performances and outstanding full-cell performances. This work provides a simple and effective way to prepare stable LCO materials working at a high voltage.

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(a) Preparation method of petal-like Ni1−xMnx(OH)2 nanosheets. SEM images of (b) Ni(OH)2, (d) Ni1−xMnx(OH)2 and (f) NiMn-LDH. TEM images of (c) Ni(OH)2, (e) Ni1−xMnx(OH)2 and (g) NiMn-LDH

(a) XRD patterns of NiMn-LDH, Ni1−xMnx(OH)2 and Ni(OH)2. (b) EDS results of Ni1−xMnx(OH)2. (c) HRTEM images and SAED patterns for Ni1−xMnx(OH)2. (d) Elemental mappings of Mn, O and Ni of Ni1−xMnx(OH)2

XPS survey spectra of Ni1−xMnx(OH)2: (a) full spectra, (b) Ni 2p, (c) Mn 2p and (d) O 1s

CV curves of cells containing (a) the variously fabricated electrodes and (b) the Ni1−xMnx(OH)2 electrode at 0.1 mV s⁻¹. (c) CV profiles of symmetric cells with different electrodes at 0.1 mV s⁻¹. (d) First charge/discharge profiles of different electrodes at 0.2C. (e) Charge/discharge voltage curves containing Ni1−xMnx(OH)2 at different rates. (f) Rate capabilities of different electrodes between 0.2 and 1C

Cycling properties of Li–S batteries containing Ni1−xMnx(OH)2, Ni(OH)2 and CNT electrodes at (a) 0.2 and (b) 0.5C. (c) Nyquist plots of Li–S batteries containing Ni1−xMnx(OH)2, Ni(OH)2 and CNT electrodes after 200 cycles. Potentiostatic discharge profiles of Li2S deposition with cells containing (d) CNT, (e) Ni(OH)2 and (f) Ni1−xMnx(OH)2 electrodes

Petal-like Mn-doped α-Ni(OH) 2 nanosheets for high-performance Li–S cathode material

March 2023

83 Reads

3 Citations

RSC Advances

[...]

Lithium-sulphur (Li-S) batteries are high-energy-density and cost-effective batteries. Herein, petal-like Ni1-x Mn x (OH)2 (x ≈ 0.04) nanosheets were synthesised using a hydrothermal method and the electrical conductivity of Ni(OH)2 was improved by applying the cathode functional materials in Li-S batteries. With up to 5 mg cm-2 of S content in the cathode, the fabricated Ni1-x Mn x (OH)2 electrode exhibited specific discharge capacities up to 1375 and 1150 mA h g-1 at 0.2 and 0.5C, and retained this capacity at 813 and 714 mA h g-1 after 200 cycles, respectively. Electrochemical measurement results show that Ni1-x Mn x (OH)2 plays a critical role in Li-S batteries as it has a larger specific surface area than Ni(OH)2, which has superior adsorption performance toward lithium polysulphides. Moreover, the conductivity performance of Ni1-x Mn x (OH)2 is significantly better than that of Ni(OH)2, which improves the electrochemical reaction kinetics of the Li-S batteries.

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Yan Zhao's research while affiliated with Dezhou University and other places

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