Rational Design of Carbon Nanomaterials for Electrochemical Sodium Storage and Capture

Kim, Jiyoung; Choi, Min Sung; Shin, Kang Ho; Kota, Manikantan; Kang, Yingbo; Lee, Soo-Jung; Lee, Jun Young; Park, Ho Seok

doi:10.1002/adma.201803444

Cited by 112 publications

(53 citation statements)

References 195 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Different forms of carbon-based materials, includingg raphite-based carbon,g raphene, and soft and hard carbons (HCs), have been investigated as anode materials in SIBs. [47] Theoretically,i th as been confirmed that Na ions can be easily intercalated into carbonaceousm aterials with an interlayer distance higher than 0.37 nm, [48] as shown in Figure 3 FIG003 a. As the interlayer distance between graphite sheets is only 0.335 nm, natural graphite only possesses al ow theoretical charge-storage capacity.S imilarly,N ai onsc annotp enetrate into voids of soft carbon due to itsi nterlayer distance (< 0.35 nm) and random orientation of layers,a nd as such Na ions tend to adsorb on the surfacea nd defects ites of soft carbon.…”

Section: Principle and Mechanismmentioning

confidence: 84%

Biomass‐Derived Carbons for Sodium‐Ion Batteries and Sodium‐Ion Capacitors

et al. 2020

View full text Add to dashboard Cite

In the past decade, the rapid development of portable electronic devices, electric vehicles, and electrical devices has stimulated extensive interest in fundamental research and the commercialization of electrochemical energy‐storage systems. Biomass‐derived carbon has garnered significant research attention as an efficient, inexpensive, and eco‐friendly active material for energy‐storage systems. Therefore, high‐performance carbonaceous materials, derived from renewable sources, have been utilized as electrode materials in sodium‐ion batteries and sodium‐ion capacitors. Herein, the charge‐storage mechanism and utilization of biomass‐derived carbon for sodium storage in batteries and capacitors are summarized. In particular, the structure–performance relationship of biomass‐derived carbon for sodium storage in the form of batteries and capacitors is discussed. Despite the fact that further research is required to optimize the process and application of biomass‐derived carbon in energy‐storage devices, the current review demonstrates the potential of carbonaceous materials for next‐generation sodium‐related energy‐storage applications.

show abstract

Section: Principle and Mechanismmentioning

confidence: 84%

Biomass‐Derived Carbons for Sodium‐Ion Batteries and Sodium‐Ion Capacitors

et al. 2020

View full text Add to dashboard Cite

show abstract

“…Carbon-based materials, with their excellent electrical, chemical, and structural properties, have been widely used as electrodes in ESS, such as supercapacitors, lithium-ion batteries, etc. [103] The porous structure and continuous connectivity of the carbon effectively transfers electrons and ions in an ESS, and it also acts as a medium for other…”

Section: Electrochemical Energy Storagementioning

confidence: 99%

Characterization, Processing, and Application of Heavy Fuel Oil Ash, an Industrial Waste Material – A Review

Basha

Aziz

Maslehuddin

et al. 2020

The Chemical Record

View full text Add to dashboard Cite

Heavy fuel oil ash (HFOA) is generated as an industrial waste material during the combustion of heavy fuel oil in power/desalination plants. With increasing energy demands, a significant volume of HFOA is generated. It is generally disposed of in landfills, causing environmental pollution, as it contains several toxic elements. Recently, efforts were made towards developing strategies for reusing industrial waste materials and creating value-added products from the waste materials. Despite significant information available in the literature on the utilization of HFOA, there is still a need for a thorough and systematic review on the characterization and utilization of HFOA in various applications. Consequently, this paper aims to present a critical review of the literature on HFOA generation, its chemical composition, physical properties, morphology, and applications. It is encouraging to note that HFOA has been used in several potential applications, such as the preparation of activated carbon and carbon nanotubes, metal recovery, environmental pollutant removal, polymer composites and construction materials, etc. However, the development of several value-added materials utilizing HFOA and its applications in other areas such as coatings, cathodic protection systems, and phase change materialswould emerge as a new topic of research. It is expected that this review will act as a precursor for further research on the use of HFOA in industrial applications. Since the use of HFOA will lead to environmental, economic, and technical benefits, research in the utilization of this industrial waste material is highly recommended.

show abstract

“…Considering the limited lithium supplies present in the earth crust (20 ppm), and the growing need for large‐scale renewable energy storage, there is a desire to develop alternative rechargeable battery chemistries based on more earth‐abundant elements, such as sodium (earth abundance 23 000 ppm), and potassium (earth abundance 17 000 ppm) . The past decade has witnessed the rapid development in sodium‐ion battery (SIB) research, whereas the potassium‐ion battery (PIB) remains much less explored . One of the main reasons for this reality is the lack of suitable high‐performance PIB anode .…”

Section: Introductionmentioning

confidence: 99%

A Site‐Selective Doping Strategy of Carbon Anodes with Remarkable K‐Ion Storage Capacity

et al. 2020

View full text Add to dashboard Cite

The limited potassium‐ion intercalation capacity of graphite hampers development of potassium‐ion batteries (PIB). Edge‐nitrogen doping is an effective approach to enhance K‐ion storage in carbonaceous materials. One shortcoming is the lack of precise control over producing the edge‐nitrogen configuration. Here, a molecular‐scale copolymer pyrolysis strategy is used to precisely control edge‐nitrogen doping in carbonaceous materials. This process results in defect‐rich, edge‐nitrogen doped carbons (ENDC) with a high nitrogen‐doping level (up to 10.5 at %) and a high edge‐nitrogen ratio (87.6 %). The optimized ENDC exhibits a high reversible capacity of 423 mAh g−1, a high initial Coulombic efficiency of 65 %, superior rate capability, and long cycle life (93.8 % retention after three months). This strategy can be extended to design other edge‐heteroatom‐rich carbons through pyrolysis of copolymers for efficient storage of various mobile ions.

show abstract

Rational Design of Carbon Nanomaterials for Electrochemical Sodium Storage and Capture

Cited by 112 publications

References 195 publications

Biomass‐Derived Carbons for Sodium‐Ion Batteries and Sodium‐Ion Capacitors

Biomass‐Derived Carbons for Sodium‐Ion Batteries and Sodium‐Ion Capacitors

Characterization, Processing, and Application of Heavy Fuel Oil Ash, an Industrial Waste Material – A Review

A Site‐Selective Doping Strategy of Carbon Anodes with Remarkable K‐Ion Storage Capacity

Contact Info

Product

Resources

About