Tin Anode for Sodium-Ion Batteries Using Natural Wood Fiber as a Mechanical Buffer and Electrolyte Reservoir

Zhu, Hongli; Jia, Zheng; Chen, Yu‐Chen; Weadock, Nicholas J.; Wan, Jiayu; Vaaland, Oeyvind; Han, Xiaogang; Li, Teng; Hu, Liangbing

doi:10.1021/nl400998t

Cited by 578 publications

(403 citation statements)

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“…Moreover, the intertwined 1D network structures can promote the charge‐transfer process and improve rate performance. Up to now, many 1D Sn‐based materials have been fabricated to be applied as anodes, such as 1D nanowires,19, 57, 59, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155 1D nanotubes,156, 157, 158, 159, 160 and 1D nanoarrays,5, 161, 162, 163, 164, 165, 166, 167 etc.…”

Section: Structure Design Of Sn‐based Anode Materialsmentioning

confidence: 99%

“…The theoretical specific capacity of Sn reaches 994 mA h g −1 for LIBs according to Li 22 Sn 5 , and 847 mA h g −1 for SIBs according to Na 15 Sn 4 19, 20. However, the drastic volume changes during Li and Na ions insertion/extraction (260% for LIBs and 420% for SIBs) always bring irreconcilable inner stress, and result in a series of negative consequences: active material particles pulverize and lose electrical connection with the current collectors, the newly formed surfaces constantly consume the Li and Na sources by forming solid electrolyte interphase (SEI) film, aggregation of particles results in poor kinetics of the electrodes, etc 12.…”

Section: Introductionmentioning

confidence: 96%

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Metallic Sn‐Based Anode Materials: Application in High‐Performance Lithium‐Ion and Sodium‐Ion Batteries

2017

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With the fast‐growing demand for green and safe energy sources, rechargeable ion batteries have gradually occupied the major current market of energy storage devices due to their advantages of high capacities, long cycling life, superior rate ability, and so on. Metallic Sn‐based anodes are perceived as one of the most promising alternatives to the conventional graphite anode and have attracted great attention due to the high theoretical capacities of Sn in both lithium‐ion batteries (LIBs) (994 mA h g−1) and sodium‐ion batteries (847 mA h g−1). Though Sony has used Sn–Co–C nanocomposites as its commercial LIB anodes, to develop even better batteries using metallic Sn‐based anodes there are still two main obstacles that must be overcome: poor cycling stability and low coulombic efficiency. In this review, the latest and most outstanding developments in metallic Sn‐based anodes for LIBs and SIBs are summarized. And it covers the modification strategies including size control, alloying, and structure design to effectually improve the electrochemical properties. The superiorities and limitations are analyzed and discussed, aiming to provide an in‐depth understanding of the theoretical works and practical developments of metallic Sn‐based anode materials.

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Section: Structure Design Of Sn‐based Anode Materialsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 96%

Metallic Sn‐Based Anode Materials: Application in High‐Performance Lithium‐Ion and Sodium‐Ion Batteries

2017

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“…[19][20][21][22][23][24][25] For example, hard carbon prepared from pyrolyzed glucose, carbon black, and carbon microspheres have been shown to exhibit initial reversible capacities of 300 mAhg -1 , 200 mAhg -1 , and 285 mAhg -1 , respectively in a Na-ion cell. [15][16][17] More recently, another hard carbon material that could deliver a reversible capacity of more than 200 mAhg -1 over 100 cycles has been reported. 22,25 However, these studies were conducted on traditional anode architecture (prepared through slurry coating of active material on metallic current collector foil and the 3 capacities reported were with respect to the active material only), either at low cycling current rates or at elevated temperatures.…”

mentioning

confidence: 99%

“…14 Novel nanostructured designs that can accommodate large volumetric strains need further exploration. [15][16][17][18] For carbon-based electrode materials, much of the emphasis has been on hard carbons due to large interlayer spacing and disordered structure. [19][20][21][22][23][24][25] For example, hard carbon prepared from pyrolyzed glucose, carbon black, and carbon microspheres have been shown to exhibit initial reversible capacities of 300 mAhg -1 , 200 mAhg -1 , and 285 mAhg -1 , respectively in a Na-ion cell.…”

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confidence: 99%

MoS₂/Graphene Composite Paper for Sodium-Ion Battery Electrodes

2014

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We study the synthesis, electrochemical and mechanical performance of layered freestanding papers composed of acid exfoliated few layer molybdenum disulfide (MoS 2 ) and reduced graphene oxide (rGO) flakes for use as a self-standing flexible electrode in sodium ion batteries. Synthesis was achieved through vacuum filtration of homogenous dispersions consisting of varying wt. % of acid treated MoS 2 flakes in GO in DI water, followed by thermal reduction at elevated temperatures. The electrochemical performance of the crumpled composite paper (at 4 mg.cm -2 ) was evaluated as counter electrode against pure Na foil in a half-cell configuration. The electrode showed good Na cycling ability with a stable charge capacity of approx.230 mAh.g -1 with respect to total weight of the electrode with coulombic efficiency reaching approx. 99 %. In addition, static uniaxial tensile tests performed on crumpled composite papers showed high average strain to failure reaching approx. %.KEYWORDS: TMDC, sodium battery, freestanding electrode, graphene, MoS 2 2 Lithium ion batteries (LIBs) have been extensively studied for energy-storage applications like portable electronic devices and electric vehicles. [1][2][3] However, concerns over the cost, safety and availability of Li reserves 4 for large-scale applications involving renewable energy integration and the electrical grid have to be answered. In this regard, sodium ion batteries (SIBs) have drawn increasing attention because in contrast to lithium, 5-7 sodium resources are practically inexhaustible and evenly distributed around the world while the ion insertion chemistry is largely identical to that of lithium. Also, from electrochemical point of view, sodium has a very negative redox potential (-2.71 V, vs. SHE) and a small electrochemical equivalent (0.86 gAh -1 ), which make it the most advantageous element for battery applications after lithium. However, many challenges remain before SIBs can become commercially competitive with LIBs. For instance, Na ions are about 55% larger in radius than Li-ions, which makes it difficult to find a suitable host material to allow reversible and rapid ion insertion and extraction. 8 To this end, researchers have proposed a number of high-capacity sodium host materials (negative electrode) involving either carbon or group IVA and VA elements that form intermetallic compounds with Na. [9][10][11][12][13] The alloying compounds demonstrate high first cycle Na-storage capacities, such as Na 15 Sn 4 (847 mAhg -1 ), Na 15 Pb 4 (485 mAhg -1 ), Na 3 Sb (600 mAhg -1 ) and Na 3 P (2560 mAhg -1 ), respectively. However, this comes at the cost of very high volume change upon Na-insertion (as much as 500 % in some cases), resulting in formation of internal cracks, loss of electrical contact, and eventual failure of the electrode (particularly for thick electrodes). 14 Novel nanostructured designs that can accommodate large volumetric strains need further exploration. [15][16][17][18] For carbon-based electrode materials, much of the emphasis ...

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“…As an anode electrode, Sn is expected to react with sodium to form fully sodiated crystalline Na 15 Sn 4 , delivering a theoretical capacity of 847 mAh g −1 106. Furthermore, the redox potentials for the formation of Na‐Sn alloys are a few hundred mV lower than those of Li–Sn alloys.…”

Section: Multi‐electron Reactions In Libs and Nibsmentioning

confidence: 99%

Advanced High Energy Density Secondary Batteries with Multi‐Electron Reaction Materials

et al. 2016

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Secondary batteries have become important for smart grid and electric vehicle applications, and massive effort has been dedicated to optimizing the current generation and improving their energy density. Multi‐electron chemistry has paved a new path for the breaking of the barriers that exist in traditional battery research and applications, and provided new ideas for developing new battery systems that meet energy density requirements. An in‐depth understanding of multi‐electron chemistries in terms of the charge transfer mechanisms occuring during their electrochemical processes is necessary and urgent for the modification of secondary battery materials and development of secondary battery systems. In this Review, multi‐electron chemistry for high energy density electrode materials and the corresponding secondary battery systems are discussed. Specifically, four battery systems based on multi‐electron reactions are classified in this review: lithium‐ and sodium‐ion batteries based on monovalent cations; rechargeable batteries based on the insertion of polyvalent cations beyond those of alkali metals; metal–air batteries, and Li–S batteries. It is noted that challenges still exist in the development of multi‐electron chemistries that must be overcome to meet the energy density requirements of different battery systems, and much effort has more effort to be devoted to this.

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Tin Anode for Sodium-Ion Batteries Using Natural Wood Fiber as a Mechanical Buffer and Electrolyte Reservoir

Cited by 578 publications

References 33 publications

Metallic Sn‐Based Anode Materials: Application in High‐Performance Lithium‐Ion and Sodium‐Ion Batteries

Metallic Sn‐Based Anode Materials: Application in High‐Performance Lithium‐Ion and Sodium‐Ion Batteries

MoS₂/Graphene Composite Paper for Sodium-Ion Battery Electrodes

Advanced High Energy Density Secondary Batteries with Multi‐Electron Reaction Materials

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Tin Anode for Sodium-Ion Batteries Using Natural Wood Fiber as a Mechanical Buffer and Electrolyte Reservoir

Cited by 578 publications

References 33 publications

Metallic Sn‐Based Anode Materials: Application in High‐Performance Lithium‐Ion and Sodium‐Ion Batteries

Metallic Sn‐Based Anode Materials: Application in High‐Performance Lithium‐Ion and Sodium‐Ion Batteries

MoS2/Graphene Composite Paper for Sodium-Ion Battery Electrodes

Advanced High Energy Density Secondary Batteries with Multi‐Electron Reaction Materials

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Product

Resources

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MoS₂/Graphene Composite Paper for Sodium-Ion Battery Electrodes