Nanostructures of solid electrolyte interphases and their consequences for microsized Sn anodes in sodium ion batteries

Huang, Jiaqiang; Guo, Xuyun; Du, Xiaoqiong; Lin, Xiuyi; Huang, Jian; Tan, Hong; Zhu, Ye; Zhang, Biao

doi:10.1039/c8ee03632b

Cited by 177 publications

(158 citation statements)

References 44 publications

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“…The polyether with abundant CO bonds was reported to exhibit high ion conductivity like the poly(ethylene oxide) electrolyte for high rate batteries. [ 15,43 ] Considering the inorganic component, such as NaF and Na 2 CO 3 , usually possess low ionic conductivity as 10 −21 –10 −31 S cm −1 . The increased sodium‐ion storage kinetics could be attributed the highly ionic conductive polyether‐like component in DME‐derived SEI, as verified by the discussion of electrochemical impedance spectroscopy (EIS) and GITT (Figures 3e,f and 4d).…”

Section: Resultsmentioning

confidence: 99%

“…The similar behavior was also found in Sn‐ or Fe‐based anode, which was involved in the formation of the SEI. [ 15,51 ] The chemical bonding of Bi with ether‐based electrolyte might be attributed to the high activity of intermediates produced during the decomposition of DME, which has a less steric hindrance compared to that derived from DEC as described in Equations [S11]–[S13], Supporting Information. The X‐ray diffraction (XRD) patterns of the Bi/C anode after 10 cycles in the DME‐ and EC/DEC‐based electrolyte (Figure S17, Supporting Information) show that all the peaks were assigned to the hexagonal Bi phase (PDF#44–1246) and no other peaks appeared in the two electrolytes.…”

Section: Resultsmentioning

confidence: 99%

“…Moreover, the enhanced electrochemical performance was also proven to be effective even in the alloying‐type anode with large volume expansion. [ 13–21 ] The enhanced performance of bulk bismuth in an ether‐based electrolyte was first reported by Chen’s group; [ 19 ] the microsized bulk bismuth could be incorporated into a porous architecture during the cycling, which ensures continuous sodium‐ion transport and structural stability for over 2000 cycles. Motivated by an intriguing phenomenon where the SEI itself was associated with the cyclic stability, the sodium storage performances could be further enhanced by matching ether‐based electrolytes with bismuth‐based composite materials, such as Bi@C, [ 22 ] Bi/N‐C, [ 23 ] Bi/graphite, [ 24 ] and Bi/graphene.…”

Section: Introductionmentioning

confidence: 99%

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Ionic‐Conducting and Robust Multilayered Solid Electrolyte Interphases for Greatly Improved Rate and Cycling Capabilities of Sodium Ion Full Cells

Yuan

Wei

et al. 2020

Advanced Energy Materials

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and similar electrochemistry to lithiumion batteries (LIBs) for energy storage applications. Despite these advantages of SIBs, their energy density is still much lower than that of LIBs. [1-5] Accordingly, high-capacity alloy-type materials are being considered as potential anodes to achieve high-energy SIBs. However, the huge volume change and sluggish chargestorage kinetics of the alloying anodes limit their practical and industrial applications. The repeated volume changes can destroy the preformed solid electrolyte interface (SEI), resulting in the continuous decomposition of the electrolyte. Consequently, the subsequent accumulation of thick SEI films will greatly impede the transfer of ions/electrons and deplete the active mass of the battery. [6,7] Among the various alloy-type anode materials under consideration for SIBs, bismuth is attractive because of its high reversible capacity (385 mAh g −1) and low operating voltage (≈0.6 V). Additionally, the large lattice fringe along the c-axis (d (003) = 3.95 Å) allows bismuth to insert/extract large-sized ions in a reversible manner during the charging and discharging cycles. However, bismuth is limited by low cyclic and rate performances arising from the large volume expansion and sluggish electrode kinetics, which are commonly observed in alloy-type anodes. For the past few years, tremendous efforts have been devoted to improving the cyclic stability by modifying alloying materials through carbon coating, porous architectures, and nanostructural designs. [8-11] The nanostructure of the bismuth anode was capable of achieving less or even zero strain for SEI formation, as well as providing a fast electron/ion transfer pathway for enhanced rate capabilities. For example, the Bi@ graphene nanocomposite and bismuth nanodots confined in the metal-organic framework derived carbon arrays exhibited dramatic improvement, in terms of their specific capacity. [12] However, the capacity decreased at high rates and after longterm cyclic tests. Thus, the sodium storage performance of the nanostructured bismuth-based anodes was not yet satisfactory. Another approach was to develop a new electrolyte and to modify the associated interface. Recently, it was reported that The energy storage performance of sodium-ion batteries has been greatly improved by pairing ether-based electrolytes with high-capacity alloy-type anodes. However, the origin of this performance improvement by a unique electrode/electrolyte interface has yet to be explored. To understand such results, herein, the deterministic and distinct interfacial chemistries and solid electrolyte interphase (SEI) layers in both the ether-and ester-based electrolytes are described, as verified by post mortem, in-depth X-ray photoelectron spectroscopy, and electron energy loss spectroscopy analyses, employing a hierarchical Bi/C composite anode as the model system. In the ether-based electrolyte, fast sodium-ion storage kinetics and structural integrity are achieved due to the highly ionic-conducting and robust multi-layered...

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Ionic‐Conducting and Robust Multilayered Solid Electrolyte Interphases for Greatly Improved Rate and Cycling Capabilities of Sodium Ion Full Cells

Yuan

Wei

et al. 2020

Advanced Energy Materials

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“…[40] On the contrary,t he force responses in other electrolytes include an elastic region, regions of slope change induced by plastic or hardening processes,a nd regions of decreased force-possibly because of fracture and tip sliding. [40] Irreversible plastic deformation damages surface morphology,w hile elastic deformation contributes to relieving strain and maintaining integrity during the potassiationdepotassiation process.T hese results show that the NCS@RGO-2 electrode in the KFSI-EP electrolyte can form at hinner and more robust SEI layer. Thee xcellent mechan-ical properties of the SEI layer facilitate the contact between electrode and electrolyte,w hich endows the electrode with extra stability against volume expansion.…”

Section: Angewandte Chemiementioning

confidence: 99%

“…Forschungsartikel smoother than those obtained using other electrolytes, indicating that KFSI-EP is helpful for formation of thinner SEI layers on the surface of electrodes and exhibits fewer side reactions than other electrolytes.T he corresponding forcedisplacement curves and their detailed analyses were obtained by AFM and are presented in Figure 5i-p.T he force responses in KFSI-EP electrolyte include an elastic region and aregion of slope change induced by the response from the electrode. [40] On the contrary,t he force responses in other electrolytes include an elastic region, regions of slope change induced by plastic or hardening processes,a nd regions of decreased force-possibly because of fracture and tip sliding. [40] Irreversible plastic deformation damages surface morphology,w hile elastic deformation contributes to relieving strain and maintaining integrity during the potassiationdepotassiation process.T hese results show that the NCS@RGO-2 electrode in the KFSI-EP electrolyte can form at hinner and more robust SEI layer.…”

Section: Angewandte Chemiementioning

confidence: 99%

A Robust Solid Electrolyte Interphase Layer Augments the Ion Storage Capacity of Bimetallic‐Sulfide‐Containing Potassium‐Ion Batteries

et al. 2019

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Metal-organic framework-derived NiCo 2.5 S 4 microrods wrapped in reduced graphene oxide (NCS@RGO) were synthesized for potassium-ion storage.Upon coordination with organic potassium salts,N CS@RGO exhibits an ultrahigh initial reversible specific capacity (602 mAh g À1 at 50 mA g À1 ) and ultralong cycle life (a reversible specific capacity of 495 mAh g À1 at 200 mA g À1 after 1900 cycles over 314 days). Furthermore,t he battery demonstrates ah igh initial Coulombic efficiency of 78 %, outperforming most sulfides reported previously.A dvanced ex situ characterization techniques,i ncluding atomic force microscopy, were used for evaluation and the results indicate that the organic potassium salt-containing electrolyte helps to form thin and robust solid electrolyte interphase layers,w hichr educe the formation of byproducts during the potassiation-depotassiation process and enhance the mechanical stability of electrodes.T he excellent conductivity of the RGO in the composites,a nd the robust interface between the electrodes and electrolytes,i mbue the electrode with useful properties;i ncluding,u ltrafast potassium-ion storage with areversible specific capacity of 402 mAh g À1 even at 2Ag À1 .

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A Self‐Healing Volume Variation Three‐Dimensional Continuous Bulk Porous Bismuth for Ultrafast Sodium Storage

Cheng

Shao

et al. 2021

Adv Funct Materials

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Bismuth (Bi) has attracted considerable attention as promising anode material for sodium-ion batteries (NIBs) owing to its suitable reaction potential and high volumetric capacity density (3750 mA h cm −3 ). However, the large volumetric expansion during cycling causes severe structural degradation and fast capacity decay. Herein, by rational design, a self-healing nanostructure 3D continuous bulk porous bismuth (3DPBi) is prepared via facile liquid phase reduction reaction. The 3D interconnected Bi nanoligaments provide unblocked electronic circuits and short ion diffusion path. Meanwhile, the bicontinuous nanoporous network can realize self-healing the huge volume variation as confirmed by in situ and ex situ transmission electron microscopy observations. When used as the anode for NIBs, the 3DPBi delivers unprecedented rate capability (high capacity retention of 95.6% at an ultrahigh current density of 60 A g −1 with respect to 1 A g −1 ) and long-cycle life (high capacity of 378 mA h g −1 remained after 3000 cycles at 10 A g −1 ). In addition, the full cell of Na 3 V 2 (PO 4 ) 3 |3DPBi delivers stable cycling performance and high gravimetric energy density (116 Wh kg −1 ), demonstrating its potential in practical application.

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Nanostructures of solid electrolyte interphases and their consequences for microsized Sn anodes in sodium ion batteries

Abstract: An optimized solid electrolyte interphase is the key to stabilization of microparticle anodes.

Cited by 177 publications

References 44 publications

Ionic‐Conducting and Robust Multilayered Solid Electrolyte Interphases for Greatly Improved Rate and Cycling Capabilities of Sodium Ion Full Cells

Ionic‐Conducting and Robust Multilayered Solid Electrolyte Interphases for Greatly Improved Rate and Cycling Capabilities of Sodium Ion Full Cells

A Robust Solid Electrolyte Interphase Layer Augments the Ion Storage Capacity of Bimetallic‐Sulfide‐Containing Potassium‐Ion Batteries

A Self‐Healing Volume Variation Three‐Dimensional Continuous Bulk Porous Bismuth for Ultrafast Sodium Storage

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