Synergistic Coupling of Ether Electrolyte and 3D Electrode Enables Titanates with Extraordinary Coulombic Efficiency and Rate Performance for Sodium‐Ion Capacitors

Gui, Qiuyue; Ba, Deliang; Zhao, Zhenshuai; Mao, Yanfang; Zhu, Weihua; Lei, Tianyu; Tan, Jianfeng; Deng, Bohua; Liang, Xiao; Li, Yuanyuan; Liu, Jinping

doi:10.1002/smtd.201800371

Cited by 43 publications

(29 citation statements)

References 79 publications

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“…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%

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: Introductionmentioning

confidence: 99%

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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“…Flexible energy storage devices require not only high energy and power densities, but also good mechanical properties to ensure robust flexibility or bendability. As a result, a promising design principle of using binder-free electrode-based hybrid capacitors was recently proposed by our group [15,[62][63]. The direct growth of three-dimensional (3D) electrode architecture on flexible current collectors has been proven to fulfil all the electrochemical and mechanical requirements for advanced flexible LICs [64].…”

Section: Introductionmentioning

confidence: 99%

Post-annealing tailored 3D cross-linked TiNb2O7 nanorod electrode: towards superior lithium storage for flexible lithium-ion capacitors

et al. 2019

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TiNb 2 O 7 anode materials (TNO) have unique potential for applications in Li-ion capacitors (LICs) due to their high specific capacity of ca. 280 mA h g −1 over a wide anodic Li-insertion potential window. However, their highrate capability is limited by their poor electronic and ionic conductivity. In particular, studies on TNO for LICs are lacking and that for flexible LICs have not yet been reported. Herein, a unique TNO porous electrode with cross-linked nanorods tailored by post-annealing and its application in flexible LICs are reported. This binder-free TNO anode exhibits superior rate performance (~66.3% capacity retention as the rate increases from 1 to 40 C), which is ascribed to the greatly shortened ion-diffusion length in TNO nanorods, facile electrolyte penetration and fast electron transport along the continuous single-crystalline nanorod network. Furthermore, the TNO anode shows an excellent cycling stability up to 2000 cycles and good flexibility (no capacity loss after continuous bending for 500 times). Model flexible LIC assembled with the TNO anode and activated carbon cathode exhibits increased gravimetric and volumetric energy/power densities (~100.6 W h kg −1 /4108.8 W kg −1 ; 10.7 mW h cm −3 / 419.3 mW cm −3 ), more superior to previously reported hybrid supercapacitors. The device also efficiently powers an LED light upon 180°bending. Figure 1 Schematic illustration of the merits of TNO electrode architecture for Li-ion storage.

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“…In this case, a higher ICE value of 95.4% can be achieved for MoSe 2 @HBC in the NaCF 3 SO 3 /diglyme electrolyte, which is mainly due to a very thin and stable SEI. [38] However, the specific capacity becomes relatively lower in NaCF 3 SO 3 /diglyme (e.g., 288.9 mA h g −1 at 10 A g −1 ) than in NaClO 4 /PC (e.g., 391.2 mA h g −1 at 10 A g −1 ) (Figure 4c). Considering the anode will undergo electrochemical activation before the assembly of SICs, [39] here we focus on achieving high Nastorage capacities.…”

Section: Na Ion Storage Properties Of Mose 2 @Hbcmentioning

confidence: 98%

In Situ Hard‐Template Synthesis of Hollow Bowl‐Like Carbon: A Potential Versatile Platform for Sodium and Zinc Ion Capacitors

Fei

Wang

et al. 2020

Advanced Energy Materials

160

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Metal‐ion capacitors are being widely studied to reach a balance between power and energy output by combining the merits of conventional batteries and capacitors. The main challenge for Na‐ion capacitors is that the battery‐type anode usually has unsatisfactory power density and long‐term stability since most Na host materials have a poor kinetic and structural stability. Herein, asymmetric hollow bowl‐like carbon (HBC) materials are rationally designed and fabricated through an in situ hard‐template approach. The formation originates from a subtle control of capillary force and the mechanical strength of the carbon shell. The HBCs possess abundant mesopores, high volumes of accessible surface area as well as an open macropore network. As a 3D host, MoSe2 nanocrystals are anchored onto the HBC matrix by a solid‐phase reaction. The obtained MoSe2@HBC nanobowl electrode exhibits pseudocapacitive sodium storage with fast kinetics, improved capacity at high currents, and cycle stability, which is also supported by DFT calculations. Sodium ion capacitor full cells are fabricated using the two bowl‐like architectures (MoSe2@HBC as the anode and HBC as the cathode), which deliver high energy and power densities, long cycle life, and a comparably low self‐discharge rate. Moreover, application of the HBC in a zinc‐ion capacitor (ZIC) is also demonstrated.

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Synergistic Coupling of Ether Electrolyte and 3D Electrode Enables Titanates with Extraordinary Coulombic Efficiency and Rate Performance for Sodium‐Ion Capacitors

Cited by 43 publications

References 79 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

Post-annealing tailored 3D cross-linked TiNb2O7 nanorod electrode: towards superior lithium storage for flexible lithium-ion capacitors

In Situ Hard‐Template Synthesis of Hollow Bowl‐Like Carbon: A Potential Versatile Platform for Sodium and Zinc Ion Capacitors

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