Synergic Effect of Niobium Doping and Carbon Coating on the Performance of a Li2ZnTi3O8 Anode Candidate for Lithium Ion Batteries

Firdous, Naila; Arshad, Nasima; Norby, Poul

doi:10.1021/acs.energyfuels.0c02819

Cited by 7 publications

(5 citation statements)

References 25 publications

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“…S4, a broad peak appears at about 0.7 V during the first negative scan, which can be attributed to the formation of SEI. 36 The redox peaks correspond to the delithiation/lithiation process of graphite and correspond well to the platform of the charge-discharge curves. The redox peak of SPAPE/NG-20 in the voltage range is more obvious and the peak surface area is larger, indicating that its redox activity is higher than that of NG electrode.…”

Section: Resultssupporting

confidence: 57%

Construction of Artificial SEI on Graphite Electrode through Electropolymerization of p-Sulfonated Polyallyl Phenyl Ether

Cai,

Xiang,

Wang

et al. 2024

J. Electrochem. Soc.

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The artificial inert layer is a dense passivation film formed on the electrode, which can effectively maintain the phase stability of the electrode. Here, p-sulfonated allyl phenyl ether monomer (SAPE) was prepared and a layer of polymer coating with ionic conductivity was electropolymerized on the surface of a graphite electrode as an artificial solid electrolyte interphase (SEI) film using cyclic voltammetry. The overall electrochemical performance of lithium ion batteries can be significantly improved by using p-sulfonated polyallyl phenyl ether/graphite composites (SPAPE/NG) as cathode materials for lithium ion batteries. The large amount of sulphonic acid groups in SPAPE is beneficial to improving the lithium ion transport rate at the graphite electrode interface, and the polymer layer can effectively inhibit the adverse side reactions at the electrode/electrolyte interface. The SPAPE/NG electrode with 20 cycles of electropolymerizing shows the best electrochemical performance. After 150 cycles at a 0.2C rate, the SPAPE/NG electrode still retains a discharge specific capacity of 221.6 mAh·g-1, which is higher than that of the pure graphite electrode (155.3 mAh·g-1).

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Section: Resultssupporting

confidence: 57%

Construction of Artificial SEI on Graphite Electrode through Electropolymerization of p-Sulfonated Polyallyl Phenyl Ether

Cai,

Xiang,

Wang

et al. 2024

J. Electrochem. Soc.

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“…For example, carbon ( Qin et al, 2020 ; Wang et al, 2021 ; Bai et al, 2022 ) or conductive compound ( Yang et al, 2017 ; Yang et al, 2019 ; Qiu et al, 2021 ) coating can enhance the surface electronic conductivity and decrease the particle size of LZTO. Metal ion doping ( Firdous et al, 2020 ; Ma et al, 2021 ; Qi et al, 2021 ; Tang et al, 2021 ) can improve the intrinsic electronic conductivity and stabilize the structure of LZTO. Nano-sized LZTO can shorten the diffusion distances of Li + ions ( Xu et al, 2013 ; Wang et al, 2016 ; Lan et al, 2017 ).…”

Section: Introductionmentioning

confidence: 99%

Polycrystal Li2ZnTi3O8/C anode with lotus seedpod structure for high-performance lithium storage

et al. 2023

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Lotus-seedpod structured Li2ZnTi3O8/C (P-LZTO) microspheres obtained by the molten salt method are reported for the first time. The received phase-pure Li2ZnTi3O8 nanoparticles are inserted into the carbon matrix homogeneously to form a Lotus-seedpod structure, as confirmed by the morphological and structural measurements. As the anode for lithium-ion batteries, the P-LZTO material demonstrates excellent electrochemical performance with a high rate capacity of 193.2 mAh g-1 at 5 A g-1 and long-term cyclic stability up to 300 cycles at 1 A g-1. After even 300 cyclings, the P-LZTO particles can maintain their morphological and structural integrity. The superior electrochemical performances have arisen from the unique structure where the polycrystalline structure is beneficial for shorting the lithium-ion diffusion path, while the well-encapsulated carbon matrix can not only enhance the electronic conductivity of the composite but also alleviate the stress anisotropy during lithiation/delithiation process, leading to well-preserved particles.

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“…For the potential metal ( M ) candidates for a Li 2 M Ti 3 O 8 anode of ion batteries, we selected zinc (Zn), 6 cobalt (Co) 7 and copper (Cu) 8…”

Section: Introductionmentioning

confidence: 99%

“…Thus, such a structure causes increased stability with respect to the formation of Li dendrites. 5 For the potential metal (M) candidates for a Li 2 MTi 3 O 8 anode of ion batteries, we selected zinc (Zn), 6 cobalt (Co) 7 and copper (Cu). 8 In order to obtain Li titanates, a high-temperature solid-state synthesis method is used that provides the formation of dense ceramics by sintering a stoichiometric mixture of powders of titanium dioxide (TiO 2 ), lithium carbonate (Li 2 CO 3 ) and zinc oxide (ZnO) or acetate (synthesis of Li 2 ZnTi 3 O 8…”

Section: Introductionmentioning

confidence: 99%

Comparison of different methods for Li₂MTi₃O₈ (M – Co, Cu, Zn) synthesis

Мацукевич

Кулак

Palkhouskaya

et al. 2021

J of Chemical Tech & Biotech

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BACKGROUND Mesoporous powders of lithium titanates Li2MTi3O8 (M – Co, Cu, Zn) of spinel structure are promising as anode materials for Li‐ion batteries. RESULTS Li2MTi3O8 (M – Co, Cu, Zn) were obtained by the sol–gel method, using self‐propagating high‐temperature synthesis (SHS) from glycine–citrate–nitrate mixtures, and also by the SHS method from aqueous solutions. The crystal structure, phase composition, microstructure and dispersion of the obtained materials were studied. CONCLUSION It was established that the SHS method for the synthesis of lithium titanates has several advantages compared with the sol–gel method, including not requiring solvents, reduced aggregation of particles, a higher specific surface area and low bulk density of the obtained powders. The electrode obtained on the basis of Zn‐containing Li titanate by the SHS method from glycine–citrate–nitrate mixtures showed the highest charging capacity of 160 mAh g−1 and high cyclic stability. © 2021 Society of Chemical Industry (SCI).

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Synergic Effect of Niobium Doping and Carbon Coating on the Performance of a Li₂ZnTi₃O₈ Anode Candidate for Lithium Ion Batteries

Cited by 7 publications

References 25 publications

Construction of Artificial SEI on Graphite Electrode through Electropolymerization of p-Sulfonated Polyallyl Phenyl Ether

Construction of Artificial SEI on Graphite Electrode through Electropolymerization of p-Sulfonated Polyallyl Phenyl Ether

Polycrystal Li2ZnTi3O8/C anode with lotus seedpod structure for high-performance lithium storage

Comparison of different methods for Li₂MTi₃O₈ (M – Co, Cu, Zn) synthesis

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Synergic Effect of Niobium Doping and Carbon Coating on the Performance of a Li2ZnTi3O8 Anode Candidate for Lithium Ion Batteries

Cited by 7 publications

References 25 publications

Construction of Artificial SEI on Graphite Electrode through Electropolymerization of p-Sulfonated Polyallyl Phenyl Ether

Construction of Artificial SEI on Graphite Electrode through Electropolymerization of p-Sulfonated Polyallyl Phenyl Ether

Polycrystal Li2ZnTi3O8/C anode with lotus seedpod structure for high-performance lithium storage

Comparison of different methods for Li2MTi3O8 (M – Co, Cu, Zn) synthesis

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Product

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Synergic Effect of Niobium Doping and Carbon Coating on the Performance of a Li₂ZnTi₃O₈ Anode Candidate for Lithium Ion Batteries

Comparison of different methods for Li₂MTi₃O₈ (M – Co, Cu, Zn) synthesis