High Capacity of Hard Carbon Anode in Na-Ion Batteries Unlocked by PO<sub><i>x</i></sub> Doping

Li, Zhifei; Ma, Lu; Surta, T. Wesley; Bommier, Clement; Jian, Zelang; Xing, Zhenyu; Stickle, William F.; Dolgos, Michelle R.; Amine, Khalil; Lü, Jun; Wu, Tianpin; Ji, Xiulei

doi:10.1021/acsenergylett.6b00172

Cited by 182 publications

(144 citation statements)

References 74 publications

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“…[55] Thus, dopings of this nature,w hich can have ad irect impact on capacity and stabilitye nhance-ments through the nanovoid regime, can be and should be implemented to desirable effect. Heteroatoms, such as N, S, and P, increase the electrode-electrolyte wettability,i na ddition to electrode conductivity enhancement through mediation in electron delocalization.…”

Section: Discussionmentioning

confidence: 99%

“…[49,50] The enlarged interlayer spacinga nd increased defect concentration contribute to the increase in the storage capacityt hrough the intercalation mechanism.T he major gains achievablef rom heteroatom doping strategies have been through the intercalation-deintercalation paths, which have been made facile by increasing the interlayer separations and barrierr eduction for intercalation reactions.T he defects ites developed in the hard carbon structure throughh eteroatom doping also help to improve the electrode-electrolyte interface by facilitating better wetting. [55] Nitrogen-doped hard carbon systems have been welle xplored as anode materials for SIBs. [51][52][53][54] Doping with certain groups,s uch as PO x ,i sn oted to lead to substantial enhancement in capacitive storaget hrough the sodiump ore-filling mechanism,a part from minor enhancements in intercalation capacities.…”

Section: Effect Of Heteroatom Doping On Capacitymentioning

confidence: 99%

“…More recently,doping with the PO x functional group was implemented by Li et al [55] Such doping in hard carbon was achieved by treating the carbon source with H 3 PO 4 ,b ut to avoid the generationo fm icroporosity,g raphene oxide was added during the pyrolysis reaction.…”

Section: Effect Of Heteroatom Doping On Capacitymentioning

confidence: 99%

“…[30] Figure 20. [55]. Simulatedc harge distribution for graphene/Nasystems with Na binding energies for graphene with d) monoand e) divacancies and f) large in-planedefects.…”

Section: Hard Carbons Derived From Oligo-and Monomersmentioning

confidence: 99%

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Hard Carbons for Sodium‐Ion Battery Anodes: Synthetic Strategies, Material Properties, and Storage Mechanisms

et al. 2018

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Sodium-ion batteries are attracting much interest due to their potential as viable future alternatives for lithium-ion batteries, in view of the much higher earth abundance of sodium over that of lithium. Although both battery systems have basically similar chemistries, the key celebrated negative electrode in lithium battery, namely, graphite, is unavailable for the sodium-ion battery due to the larger size of the sodium ion. This need is satisfied by "hard carbon", which can internalize the larger sodium ion and has desirable electrochemical properties. Unlike graphite, with its specific layered structure, however, hard carbon occurs in diverse microstructural states. Herein, the relationships between precursor choices, synthetic protocols, microstructural states, and performance features of hard carbon forms in the context of sodium-ion battery applications are elucidated. Derived from the pertinent literature employing classical and modern structural characterization techniques, various issues related to microstructure, morphology, defects, and heteroatom doping are discussed. Finally, an outlook is presented to suggest emerging research directions.

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Section: Discussionmentioning

confidence: 99%

Section: Effect Of Heteroatom Doping On Capacitymentioning

confidence: 99%

Section: Effect Of Heteroatom Doping On Capacitymentioning

confidence: 99%

“…[30] Figure 20. [55]. Simulatedc harge distribution for graphene/Nasystems with Na binding energies for graphene with d) monoand e) divacancies and f) large in-planedefects.…”

Section: Hard Carbons Derived From Oligo-and Monomersmentioning

confidence: 99%

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Hard Carbons for Sodium‐Ion Battery Anodes: Synthetic Strategies, Material Properties, and Storage Mechanisms

et al. 2018

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“…It has been shown that the composition [25,60] and quality [61] of the electrolyte influence strongly on the amount of charge lost for the SEI formation. Despite recent reports about tuning the porosity through PO x doping, [65] or demonstrating the correlation between pore size and capacity, [43] a deeper understanding of the mechanism of charge storage and its correlation with microstructural features appears necessary. [48] Some strategies have been successfully used to increase the coulombic efficiency by reducing the specific surface area, such as carbon coating [62,63] or the use of a graphene additive mixed with the precursor prior to pyrolysis.…”

Section: Electrochemical Performance and Optimizationmentioning

confidence: 99%

Na‐Ion Batteries for Large Scale Applications: A Review on Anode Materials and Solid Electrolyte Interphase Formation

Muñoz‐Márquez

Saurel

Gómez-Cámer

et al. 2017

Advanced Energy Materials

281

196

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Once lithium-ion battery (LIB) technology has reached a maturity level enough to be the battery of choice for consumer electronics and power tools, it will be very well positioned to take over transport applications while displacing, for instance, NiCd and Ni-MH technologies. However, a major challenge is waiting for us in the near term: large scale and low cost stationary energy storage. This will be crucial for boosting the efficiency, adaptability, and reliability of the next-generation power grid. The use of stationary energy storage systems coupled to the The urgent need for optimizing the available energy through smart grids and efficient large-scale energy storage systems is pushing the construction and deployment of Li-ion batteries in the MW range which, in the long term, are expected to hit the GW dimension while demanding over 1000 ton of positive active material per system. This amount of Li-based material is equivalent to almost 1% of current Li consumption and can strongly influence the evolution of the lithium supply and cost. Given this uncertainty, it becomes mandatory to develop an energy storage technology that depends on almost infinite and widespread resources: Na-ion batteries are the best technology for large-scale applications. With small working cells in the market that cannot compete in cost ($/W h) with commercial Li-ion batteries, the consolidation of Na-ion batteries mainly depends on increasing their energy density and stability, the negative electrodes being at the heart of these two requirements. Promising Na-based negative electrodes for large-scale battery applications are reviewed, along with the study of the solid electrolyte interphase formed in the anode surface, which is at the origin of most of the stability problems.

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Recent Progress in Hard Carbon Anodes for Sodium‐Ion Batteries

Wang,

Xi,

Peng

et al. 2024

Adv Eng Mater

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With the rapid development of renewable energy and the growth of energy demand, sodium‐ion batteries have attracted much attention from researchers as a promising energy storage technology. Hard carbon anodes are considered to be the most promising anodes of sodium‐ion batteries because of their low sodium storage potential, high capacity, wide range of raw materials, and environmental friendliness. However, the rate capability and initial coulombic efficiency of hard carbon hinder the further commercialization of hard carbon. This review provides a concise overview of the three microstructures and four sodium storage mechanisms of hard carbon and comprehensively introduces the latest research progress on strategies to effectively improve the electrochemical performance of hard carbon anodes, which are categorized into structural and morphology design, precursors selection, electrolyte optimization, surface engineering and pre‐sodiation as modification strategies. In addition, we also encapsulate the current research progress on sodium‐ion full batteries and look forward to the developmental prospects of hard carbon anodes in sodium‐ion batteries.This article is protected by copyright. All rights reserved.

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High Capacity of Hard Carbon Anode in Na-Ion Batteries Unlocked by PO_x Doping

Cited by 182 publications

References 74 publications

Hard Carbons for Sodium‐Ion Battery Anodes: Synthetic Strategies, Material Properties, and Storage Mechanisms

Hard Carbons for Sodium‐Ion Battery Anodes: Synthetic Strategies, Material Properties, and Storage Mechanisms

Na‐Ion Batteries for Large Scale Applications: A Review on Anode Materials and Solid Electrolyte Interphase Formation

Recent Progress in Hard Carbon Anodes for Sodium‐Ion Batteries

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High Capacity of Hard Carbon Anode in Na-Ion Batteries Unlocked by POx Doping

Cited by 182 publications

References 74 publications

Hard Carbons for Sodium‐Ion Battery Anodes: Synthetic Strategies, Material Properties, and Storage Mechanisms

Hard Carbons for Sodium‐Ion Battery Anodes: Synthetic Strategies, Material Properties, and Storage Mechanisms

Na‐Ion Batteries for Large Scale Applications: A Review on Anode Materials and Solid Electrolyte Interphase Formation

Recent Progress in Hard Carbon Anodes for Sodium‐Ion Batteries

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High Capacity of Hard Carbon Anode in Na-Ion Batteries Unlocked by PO_x Doping