Materials Design for High‐Safety Sodium‐Ion Battery

Yang, Chao; Xin, Sen; Mai, Liqiang; You, Ya

doi:10.1002/aenm.202000974

Cited by 320 publications

(212 citation statements)

References 173 publications

Supporting

Mentioning

209

Contrasting

Unclassified

Order By: Relevance

“…The five aspects are carefully examined and compared with other electrode materials for both SIBs and PIBs. [ 7,43–46 ] Nevertheless, how to uniformly maintain the well‐decorated carbon network and retain the highly pure phase of the electrodes on the industrial level is very challenging. The continuous rotary kiln process can be considered as an effective approach at industrial level.…”

Section: Scientific Importance Of Vanadium‐based Composites For Buildmentioning

confidence: 99%

Designing Advanced Vanadium‐Based Materials to Achieve Electrochemically Active Multielectron Reactions in Sodium/Potassium‐Ion Batteries

Chen¹,

Liu

et al. 2020

Advanced Energy Materials

View full text Add to dashboard Cite

Next‐generation sodium‐ion batteries (SIBs) and potassium‐ion batteries (PIBs) are considered to be promising alternatives to replace current lithium‐ion batteries due to the high abundance of sodium and potassium resources. New energetic vanadium‐based compounds that undergoes multielectron reactions and demonstrate good sodium/potassium storage capability, provide new solutions for high‐performance SIBs/PIBs in terms of high energy/power density and long‐time cyclability. So far, desirable rich redox centers (V2+‐V5+), consolidated frameworks, and the high theoretical capacities of vanadium‐based compounds have been widely explored for practical applications. Rational materials design utilizing vanadium multiredox centers and the fundamental understanding of their charge‐transfer processes and mechanisms are critical in the development of high‐performance battery systems. The scientific importance and basic design strategies for high performance V‐based anode/cathode materials, structure‐function properties and state‐of‐the‐art understanding of V‐based electrode materials are herein classified and highlighted alongside their design strategies. The important role of the valence electron layer of vanadium, and the scientific advances of vanadium partitions in other electrochemical behaviors are also summarized in detail. Finally, relevant strategies and perspectives discussed in this review provide practical guidance to explore the undiscovered potentials of multi‐electron reaction relationships of not only V‐based composites, but also other types of electrode materials.

show abstract

Section: Scientific Importance Of Vanadium‐based Composites For Buildmentioning

confidence: 99%

Designing Advanced Vanadium‐Based Materials to Achieve Electrochemically Active Multielectron Reactions in Sodium/Potassium‐Ion Batteries

Chen¹,

Liu

et al. 2020

Advanced Energy Materials

View full text Add to dashboard Cite

show abstract

“…Despite extensive applications in portable electronics and remarkable commercial success of lithium ion batteries, the extreme scarcity, uneven distribution, and high cost of lithium resources that are rapidly consumed in lithium ion battery industrial manufacture have caused great concerns on undersupply of sustainable lithium storage devices. [ 1 ] In order to meet the demand for energy storage market, exploitation of alternative energy storage systems with long‐term sustainability, cost‐effectiveness, and high energy density is quite urgent and important, such as sodium ion batteries, [ 2 ] sodium–sulfur batteries, [ 3 ] potassium ion batteries (PIBs), [ 4 ] zinc ion batteries, [ 5 ] aluminum ion batteries, [ 6 ] and magnesium ion batteries. [ 7 ] In very recent years, potassium, which lies in the same group with lithium, begins to come into scientists’ view due to their unique advantages.…”

Section: Introductionmentioning

confidence: 99%

Advanced High‐Performance Potassium–Chalcogen (S, Se, Te) Batteries

Huang

Sun

Wang

et al. 2021

Small

View full text Add to dashboard Cite

Current great progress on potassium‐chalcogen (S, Se, Te) batteries within much potential to become promising energy storage systems opens a new avenue for the rapid development of potassium batteries as a complementary option to lithium ion batteries. The discussion mainly concentrates on recent research advances of potassium–chalcogen (S, Se, Te) batteries and their corresponding cathode materials in this review. Initially, the development of cathode materials for four types of batteries is introduced, including: potassium–sulfur (K–S), potassium–selenium (K–Se), potassium–selenium sulfide (K–SexSy), and potassium–tellurium (K–Te) batteries. Next, critical challenges for chalcogen‐based electrodes in devices operation are summarized. In addition, some pragmatic strategies are proposed as well to relieve the low electronic conductivity, large volumetric expansion, shuttle effect, and potassium dendrite growth. At last, the perspectives on designing advanced cathode materials for potassium–chalcogen batteries are provided with the goal of developing high‐performance potassium storage devices.

show abstract

“…However, their cost disadvantage and limited global abundance cannot meet the continuous demand in large grid energy storage system 3 . As the new choice to replace LIBs in large scale stationary applications, sodium ion batteries (SIBs) were paid more and more attentions recently, because of the abundance of raw materials and safety 4‐10 . If a rechargeable sodium‐ion battery with good performance characteristics could be developed, it could have the advantage of using electrolyte systems of lower decomposition potential due to the higher half‐reaction potential for sodium relative to lithium 5,6 .…”

Section: Introductionmentioning

confidence: 99%

“…Robinson et al found that the self‐heating rate in a Na‐ion pouch cell is significantly slower than that in a commercial LiCoO 2 pouch cell and the thermal runaway process is less exothermic for Na‐ion cells, indicating that SIBs could be a potentially safer option compared with LIBs 10 . Unfortunately, the larger Na + radius (1.02 Å) caused the slower diffusion kinetics, structure damage, and severe volume expansion during the electrochemical reaction process, resulting in the low coulombic efficiency, low‐grade rate capability, and inferior storage capacity 5 . For example, the crystalline Sn nanoparticles are sodiated with Na to form Na 15 Sn 4 alloy with a great volumetric expansion of 420% 11 .…”

Section: Introductionmentioning

confidence: 99%

N, S self‐doped porous carbon with enlarged interlayer distance as anode for high performance sodium ion batteries

Zhang

Feng

et al. 2020

Int J Energy Res

View full text Add to dashboard Cite

Summary To enhance the cycling ability and rate property of carbon anode material for sodium ion battery, an easy, green, and scalable thermal pyrolysis method had been exploited to synthesize the nitrogen, sulfur self‐doped porous carbon anode derived from the walnut shell. The microstructure and electrochemical properties of this synthesized porous carbon materials are investigated by tuning the thermal pyrolysis temperature. When it is at 1000 °C, the porous carbon material exhibits the largest average interlayer distance of about 0.408 nm (d002) and excellent electrochemical performance. The porous carbon electrode material carbonized at 1000°C for sodium ion battery manifests a high reversible specific capacity of about 305 mAh g−1 at a current density of 100 mA g−1 after 200 cycles, and as large as 182 mAh g−1 at 1 A g−1 after 1500 charge/discharge cycles. Nitrogen and sulfur doped biomass carbon anode material with an excellent storage capacity for sodium ion, makes it an appealing candidate as cheap and high‐performance anode materials for sodium ion batteries.

show abstract

Materials Design for High‐Safety Sodium‐Ion Battery

Cited by 320 publications

References 173 publications

Designing Advanced Vanadium‐Based Materials to Achieve Electrochemically Active Multielectron Reactions in Sodium/Potassium‐Ion Batteries

Designing Advanced Vanadium‐Based Materials to Achieve Electrochemically Active Multielectron Reactions in Sodium/Potassium‐Ion Batteries

Advanced High‐Performance Potassium–Chalcogen (S, Se, Te) Batteries

N, S self‐doped porous carbon with enlarged interlayer distance as anode for high performance sodium ion batteries

Contact Info

Product

Resources

About