Facile Stabilization of the Sodium Metal Anode with Additives: Unexpected Key Role of Sodium Polysulfide and Adverse Effect of Sodium Nitrate

Wang, Huan; Wang, Chuanlong; Matios, Edward; Li, Weiyang

doi:10.1002/anie.201801818

Cited by 171 publications

(132 citation statements)

References 34 publications

Supporting

Mentioning

129

Contrasting

Order By: Relevance

“…Na 2 S 6 alone was found to improvet he electrochemical performance of the sodium-metal anode, even at ac urrent density as high as 10 mA cm À2 and ac apacity of 5mAh cm À2 over 100 cycles. [72] Unexpectedly,i nc ontrast to Li 2 S 6 ÀLiNO 3 ,w hich wasr eported to enhance the performance of the LiÀSb attery through as ynergistic effect, Na 2 S 6 ÀNaNO 3 was found to be detrimental on sodium metal. In an attempt to explain the startling effect, XPS analysisr evealed that the predominant SEI layer buildingm aterials,i fN a 2 S 6 alone was used, were of inorganic nature,e nlisting Na 2 O, Na 2 S 2 ,a nd Na 2 S. This, in turn, provided am echanicallys table SEI layer capable of suppressing sodium dendrite growth.…”

Section: Additives For Metal Nbrbsmentioning

confidence: 99%

“…Inspired by the analogues use of Li 2 S n −LiNO 3 in the Li−S battery, Li and co‐workers evaluated sodium polysulfide (Na 2 S 6 ) alone and as a coadditive with sodium nitrate (NaNO 3 ) in ether‐based electrolyte. Na 2 S 6 alone was found to improve the electrochemical performance of the sodium‐metal anode, even at a current density as high as 10 mA cm −2 and a capacity of 5 mAh cm −2 over 100 cycles . Unexpectedly, in contrast to Li 2 S 6 −LiNO 3 , which was reported to enhance the performance of the Li−S battery through a synergistic effect, Na 2 S 6 −NaNO 3 was found to be detrimental on sodium metal.…”

Section: Additives For Metal Nbrbsmentioning

confidence: 99%

See 1 more Smart Citation

Electrolyte Additives for Room‐Temperature, Sodium‐Based, Rechargeable Batteries

Eshetu

Martínez‐Ibáñez

Sánchez-Díez

et al. 2018

Chemistry An Asian Journal

View full text Add to dashboard Cite

Owing to resource abundance, and hence, a reduction in cost, wider global distribution, environmental benignity, and sustainability, sodium-based, rechargeable batteries are believed to be the most feasible and enthralling energy-storage devices. Accordingly, they have recently attracted attention from both the scientific and industrial communities. However, to compete with and exceed dominating lithium-ion technologies, breakthrough research is urgently needed. Among all non-electrode components of the sodium-based battery system, the electrolyte is considered to be the most critical element, and its tailored design and formulation is of top priority. The incorporation of a small dose of foreign molecules, called additives, brings vast, salient benefits to the electrolytes. Thus, this review presents progress in electrolyte additives for room-temperature, sodium-based, rechargeable batteries, by enlisting sodium-ion, Na-O /air, Na-S, and sodium-intercalated cathode type-based batteries.

show abstract

Section: Additives For Metal Nbrbsmentioning

confidence: 99%

Section: Additives For Metal Nbrbsmentioning

confidence: 99%

Electrolyte Additives for Room‐Temperature, Sodium‐Based, Rechargeable Batteries

Eshetu

Martínez‐Ibáñez

Sánchez-Díez

et al. 2018

Chemistry An Asian Journal

View full text Add to dashboard Cite

show abstract

“…Na 2 S 6 was found to boost the electrochemical performance of the Na electrode for over 100 cycles at high current density (10 mA cm −2 ) and cycled capacity (5 mAh cm −2 ). [ 290 ] However, while the combination of Li 2 S 6 and LiNO 3 is reported to enhance the performance of Li–S battery via a synergistic effect, the use of only Na 2 S 6 is preferred with Na. In fact, XPS analysis revealed that the SEI layer contains Na 2 O, Na 2 S 2 , and Na 2 O, which provide a mechanically stable SEI capable of suppressing (reducing) Na dendrite growth when only Na 2 S 6 is present ( Figure 18 a).…”

Section: Electrode/electrolyte Interphases In Sodium Batteriesmentioning

confidence: 99%

Electrolytes and Interphases in Sodium‐Based Rechargeable Batteries: Recent Advances and Perspectives

Eshetu

Elia

Armand

et al. 2020

Advanced Energy Materials

274

248

View full text Add to dashboard Cite

technologies. Unlike lithium, whose market is already very tight, sodium mineral deposits are almost infinite, evenly distributed worldwide, much easier to extract and thereby attainable at low cost. [1][2][3][4] If the realization of Na-rechargeable batteries could be practically possible, there will be nearly three orders of magnitude relaxation in the constraints on lithium-based resources, accompanied by sustainability, improved environmental benevolence, and cost reduction ( Table 1). Even more appealing is the possible use of the widely available and lighter aluminum, rather than copper, as negative current collector and hard carbon from renewable sources instead of graphite for the negative electrode. Finally, the stability of sodium-ion batteries (SIBs) in the fully discharged state would significantly enhance the safety associated with the shipment of large-format SIBs worldwide.These beneficial features of sodiumbased cells revived the research work on Na-based rechargeable batteries and accordingly captured the attention of both the academic research and industry sectors. However, similar to LIB, most of the research work in Na-based batteries have focused on the development and elaboration of negative and positive For sodium (Na)-rechargeable batteries to compete, and go beyond the currently prevailing Li-ion technologies, mastering the chemistry and accompanying phenomena is of supreme importance. Among the crucial components of the battery system, the electrolyte, which bridges the highly polarized positive and negative electrode materials, is arguably the most critical and indispensable of all. The electrolyte dictates the interfacial chemistry of the battery and the overall performance, having an influence over the practical capacity, rate capability (power), chemical/thermal stress (safety), and lifetime. In-depth knowledge of electrolyte properties provides invaluable information to improve the design, assembly, and operation of the battery. Thus, the full-scale appraisal of both tailored electrolytes and the concomitant interphases generated at the electrodes need to be prioritized. The deployment of large-format Na-based rechargeable batteries also necessitates systematic evaluation and detailed appraisal of the safety-related hazards of Na-based batteries. Hence, this review presents a comprehensive account of the progress, status, and prospect of various Na + -ion electrolytes, including solvents, salts and additives, their interphases and potential hazards.

show abstract

“…Similarly with lithium metal anode, Na metal batteries using conventional organic liquid electrolyte are facing some challenges, such as dendrite growth, volume changes, solid electrolyte interphase (SEI), suggesting an inferior cyclability and poor safety . Numerous efforts have been made to deal with abovementioned issues and obtain great achievements on the protection of sodium metal, such as artificial SEI, electrolyte additive, superconcentrated electrolyte, membrane modification, and 3D current collectors . Still, the inherent serious safety issues of the volatile and flammable of organic liquid electrolyte are like a sword hanging on the air.…”

mentioning

confidence: 99%

A Flexible Solid Electrolyte with Multilayer Structure for Sodium Metal Batteries

Ling

Yue

et al. 2020

Advanced Energy Materials

101

View full text Add to dashboard Cite

Solid electrolytes (SEs) can potentially address the inherent safety problems of conventional organic liquid electrolytes. However, their low ionic conductivity and large interfacial resistance limit the practical applications of SEs. Here, a flexible solid electrolyte with a multilayer structure is fabricated by the UV curing of an interpenetrating network of poly(ether‐acrylate) (ipn‐PEA) in the Na3Zr2Si2PO12/poly(vinylidene fluoride‐hexafluoropropylene) porous skeleton (NZSP/PVDF‐HFP), exhibiting a high Na+ transference number of 0.63 and a suitable ionic conductivity of above 10−4 S cm−1 at 60 °C. In addition, due to the unique structure of the internal rigidity and external flexibility, the composite solid electrolyte can effectively mitigate interfacial ion transfer issues while guaranteeing a certain mechanical strength, and largely inhibiting the formation of dendrite and dead sodium. The solid sodium metal batteries using Na3V2(PO4)3 (NVP) as a cathode possess a discharge capacity of 85 mA h g−1 after 100 cycles at 0.5 C, and achieve above 90% of capacity retention rate during 100 cycles at 0.1 C for Na2/3Ni1/3Mn1/3Ti1/3O2 (NTMO) at 60 °C. The flexible solid electrolyte with multilayer structure shows a great advantage for managing the ionic conductivity and interface resistance problem, suggesting a promise as a practical sodium metal battery.

show abstract

Facile Stabilization of the Sodium Metal Anode with Additives: Unexpected Key Role of Sodium Polysulfide and Adverse Effect of Sodium Nitrate

Cited by 171 publications

References 34 publications

Electrolyte Additives for Room‐Temperature, Sodium‐Based, Rechargeable Batteries

Electrolyte Additives for Room‐Temperature, Sodium‐Based, Rechargeable Batteries

Electrolytes and Interphases in Sodium‐Based Rechargeable Batteries: Recent Advances and Perspectives

A Flexible Solid Electrolyte with Multilayer Structure for Sodium Metal Batteries

Contact Info

Product

Resources

About