Present development and future perspectives on biowaste-derived hard carbon anodes for room temperature sodium-ion batteries

Rakhymbay, Lunara; Bazybek, Nardana; Kudaibergenov, Kenes; Myung, Seung-Taek; Bakenov, Zhumabay; Konarov, Aishuak

doi:10.1016/j.jpowsour.2024.234347

Cited by 8 publications

(1 citation statement)

References 158 publications

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“…On the anode side, hard carbon, a cost-effective carbonaceous material, is compelling as the first anode material applied to commercialization of SIBs like the graphite anode in LIBs. Battery manufacturer CATL Corp. recently announced it would mass-produce SIBs with the use of in-house hard carbon as the anode material, and it is obvious that hard carbon will soon be the 1st-generation commercial anode material [133]. Similar to the commercially used graphite-Si composite in LIBs using the high capacity of Si anodes, it is essential to develop a high-performance anode in SIBs that can be applied for the composite with hard carbon to compensate for the low capacity and poor rate capability of hard carbon anodes.…”

Section: Future Perspectives Regarding the Commercialization Of Sibsmentioning

confidence: 99%

Review and Recent Advances in Metal Compounds as Potential High-Performance Anodes for Sodium Ion Batteries

Choi,

Ha,

Kim

2024

Energies

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Along with great attention to eco-friendly power solutions, sodium ion batteries (SIBs) have stepped into the limelight for electrical vehicles (EVs) and grid-scale energy storage systems (ESSs). SIBs have been perceived as a bright substitute for lithium ion batteries (LIBs) due to abundance on Earth along with the cost-effectiveness of Na resources compared to Li counterparts. Nevertheless, there are still inherent challenges to commercialize SIBs due to the relatively larger ionic radius and sluggish kinetics of Na+ ions than those of Li+ ions. Particularly, exploring novel anode materials is necessary because the conventional graphite anode in LIBs is less active in Na cells and hard carbon anodes exhibit a poor rate capability. Various metal compounds have been examined for high-performance anode materials in SIBs and they exhibit different electrochemical performances depending on their compositions. In this review, we summarize and discuss the correlation between cation and anion compositions of metal compound anodes and their structural features, energy storage mechanisms, working potentials, and electrochemical performances. On top of that, we also present current research progress and numerous strategies for achieving high energy density, power, and excellent cycle stability in anode materials.

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Section: Future Perspectives Regarding the Commercialization Of Sibsmentioning

confidence: 99%

Review and Recent Advances in Metal Compounds as Potential High-Performance Anodes for Sodium Ion Batteries

Choi,

Ha,

Kim

2024

Energies

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A Facile Method to Transform Pickled Olive Wastes Into Sulfur‐Doped Carbon for Sodium‐Ion Battery Electrode

Medina,

Alcántara,

Lavela

et al. 2024

ChemSusChem

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This work provides a novel, low‐cost, and effective method to prepare disordered carbon materials for advanced sodium‐ion batteries using biomass. A large amount of olive stone waste is yearly produced in the world, and it could be re‐used for fine applications other than fuel for heat production. After treatment with sulfuric acid solution and carbonization process, wastes of olive stone are efficiently transformed into optimized carbon electrode material. XRD, XRF and XPS, electron microscopy, and physical gas adsorption are used for the compositional, microstructural, and textural characterization of the carbons. During the synthesis, impurities are removed, C‐S links are formed and micropores pores are created. Sulfuric acid acts like S‐dopant. The latent pores, or pores closed to nitrogen, can be found using CO2 adsorption, and are very suitable for accommodation for sodium. The results reveal that the reversible capacity is raised from ca. 200 mAh g‐1 to ca. 250 mAh g‐1 for the carbon obtained through treatment with sulfuric acid. The improved electrochemistry is the result of the s‐doping and the porosity.

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LiF modified hard carbon from date seeds as an anode material for enhanced low-temperature lithium-ion batteries

Issatayev,

Tassybay,

et al. 2024

Carbon

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Present development and future perspectives on biowaste-derived hard carbon anodes for room temperature sodium-ion batteries

Cited by 8 publications

References 158 publications

Review and Recent Advances in Metal Compounds as Potential High-Performance Anodes for Sodium Ion Batteries

Review and Recent Advances in Metal Compounds as Potential High-Performance Anodes for Sodium Ion Batteries

A Facile Method to Transform Pickled Olive Wastes Into Sulfur‐Doped Carbon for Sodium‐Ion Battery Electrode

LiF modified hard carbon from date seeds as an anode material for enhanced low-temperature lithium-ion batteries

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