Structure and function of hard carbon negative electrodes for sodium-ion batteries

Mittal, Uttam; Djuandhi, Lisa; Sharma, Neeraj; Andersen, Henrik L.

doi:10.1088/2515-7655/ac8dc1

Cited by 18 publications

(17 citation statements)

References 109 publications

(174 reference statements)

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“…biowaste-derived hard carbons reported in literature which are in the range of 3.7-4.2 Å. [49] This could be ascribed to the reduction of the disorder degree in the sample due to the addition of graphene as observed in our previous work. [43] The crystallite size along the c-axis (L c ) and the size of the layer planes (L a ) were 13.42 and 64.04 Å, respectively, as calculated by the Scherrer's equation.…”

Section: Resultssupporting

confidence: 61%

“…According to Bragg's Law the interlayer distance ( d 002 ) of rGOCOF corresponds to 3.50 Å, which is slightly higher than the graphene interlayered distance in graphite (3.35 Å). It is worth to remark that the interlayer distance of the graphene‐coffee waste hard carbon is slightly lower when compared to other biowaste‐derived hard carbons reported in literature which are in the range of 3.7–4.2 Å [49] . This could be ascribed to the reduction of the disorder degree in the sample due to the addition of graphene as observed in our previous work [43] .…”

Section: Resultssupporting

confidence: 52%

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Unravelling Charge Storage Mechanisms of Lithium, Sodium and Potassium into Graphene‐Coffee Waste Derived Hard Carbon Composites

Gómez‐Urbano

Leibing

Darlami-Magar

et al. 2023

Batteries & Supercaps

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Hard carbons are promising anode materials for lithium, sodium and potassium‐ion batteries attending to their low cost, simple processing technology and outstanding electrochemical performance. However, their complex structure and controversial carrier‐ion storage mechanisms makes difficult the prediction of their performance. Herein, we investigate the insertion storage mechanisms behind of three different alkali metal ions (lithium, sodium and potassium) into a hard carbon composite obtained by the pyrolysis of coffee waste and graphene oxide. The insertion/deinsertion processes have been monitored by galvanostatic intermittent titration technique and operando X‐Ray diffraction. Results reveal that alkaline metal ions follow an adsorption‐intercalation mechanism where the high potential region can be ascribed to the adsorption of the alkaline metal ions on the surface active sites, while slopping region arises from their intercalation between the pseudo‐graphitic micro‐crystallites. Moreover, the graphene‐coffee waste hard carbon exhibits a notorious capacity retention after 300 charge/discharge cycles in all the alkaline metals evaluated.

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Section: Resultssupporting

confidence: 61%

Section: Resultssupporting

confidence: 52%

Unravelling Charge Storage Mechanisms of Lithium, Sodium and Potassium into Graphene‐Coffee Waste Derived Hard Carbon Composites

Gómez‐Urbano

Leibing

Darlami-Magar

et al. 2023

Batteries & Supercaps

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Section: Nanoporesmentioning

confidence: 99%

“…However, the narrow peak centered at g = 2.002 is caused by the formation of metallic sodium. [159] Operando 23 Na ssNMR was used by Stratford et al to provide insight into the sodiation process, and showed that sodium ions are first adsorbed on the carbon surfaces in the sloping region followed by the formation of quasi-metallic clusters at the plateau region (Figure 9d). [83] Au et al used ex situ 23 Na ssNMR and total scattering to study the [162] Copyright 2017, Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences.…”

Section: Nanoporesmentioning

confidence: 99%

“…Fortunately, hard carbon anodes in SIBs show similar electrochemical performance to the graphite anode in LIBs, namely long and reversible low-potential charge/discharge plateaus (<0.1 V). [21][22][23][24] Stevens et al first reported that glucose-derived hard carbons possess a reversible capacity of ≈300 mAh g −1 , over half of which came from the plateau. [25] Since then, researchers have extensively investigated different hard carbons prepared from various precursors and with different synthesis conditions, and these have posed a great problem concerning the sodium storage mechanism and how to design ideal hard carbon anodes for commercialization.…”

Section: Introductionmentioning

confidence: 99%

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Reconfiguring Hard Carbons with Emerging Sodium‐Ion Batteries: A Perspective

Chu

Zhang

et al. 2023

Advanced Materials

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Hard carbons, an important category of amorphous carbons, are non‐graphitizable and are widely accepted as the most promising anode materials for emerging sodium‐ion batteries (SIBs)， because of their changeable low‐potential charge/discharge plateaus. However, their microstructures are not fixed and are difficult to accurately demonstrate as graphites do. The successful use of hard carbons in SIBs revives the interest to clearly picture their complicated microstructures that are in close relevance to sodium storage. In this review, the past definitions and structural models of hard carbons are revisited first, and a renewed understanding of their sodium storage is presented. Three critical structural features are highlighted for hard carbons, namely crystallites, defects, and nanopores, which are directly responsible for the presence of the low‐potential plateaus and their reversible extension. The impact of these structural features upon the sodium storage is then deeply discussed and sieving carbons is finally proposed as an ideal configuration of carbon anode for superhigh sodium storage. This review is expected to offer a clear picture of hard carbons, and help realize a truly rational design of high‐capacity carbon anodes, driving the industrialization of SIBs, and more promisingly open up a window for exploring their possible new uses.

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Vine Shoots‐Derived Hard Carbons as Anodes for Sodium‐Ion Batteries: Role of Annealing Temperature in Regulating Their Structure and Morphology

Alvira

Antorán

Vidal

et al. 2023

Batteries & Supercaps

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Sodium‐ion batteries (SIBs) are considered one of the most promising large‐scale and low‐cost energy storage systems due to the abundance and low price of sodium. Herein, hard carbons from a sustainable biomass feedstock (vine shoots) were synthesized via a simple two‐step carbonization process at different highest temperatures to be used as anodes in SIBs. The hard carbon produced at 1200 °C delivered the highest reversible capacity (270 mAh g–1 at 0.03 A g–1, with an acceptable initial coulombic efficiency of 71%) since a suitable balance between the pseudographitic domains growth and the retention of microporosity, defects, and functional groups was achieved. A prominent cycling stability with a capacity retention of 97% over 315 cycles was also attained. Comprehensive characterization unraveled a three‐stage sodium storage mechanism based on adsorption, intercalation, and filling of pores. A remarkable specific capacity underestimation of up to 38% was also found when a two‐electrode half‐cell configuration was employed to measure the rate performance. To avoid this systematic error caused by the counter/reference electrode polarization, we strongly recommend the use of a three‐electrode setup or a full‐cell configuration to correctly evaluate the anode response at moderate and high current rates.

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Structure and function of hard carbon negative electrodes for sodium-ion batteries

Cited by 18 publications

References 109 publications

Unravelling Charge Storage Mechanisms of Lithium, Sodium and Potassium into Graphene‐Coffee Waste Derived Hard Carbon Composites

Unravelling Charge Storage Mechanisms of Lithium, Sodium and Potassium into Graphene‐Coffee Waste Derived Hard Carbon Composites

Reconfiguring Hard Carbons with Emerging Sodium‐Ion Batteries: A Perspective

Vine Shoots‐Derived Hard Carbons as Anodes for Sodium‐Ion Batteries: Role of Annealing Temperature in Regulating Their Structure and Morphology

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