Pulverization‐Tolerance and Capacity Recovery of Copper Sulfide for High‐Performance Sodium Storage

Park, Jae Yeol; Kim, Sung Joo; Yim, Kanghoon; Dae, Kyun Seong; Lee, Yonghee; Dao, Khoi Phuong; Park, Jisu; Jeong, Han Beom; Chang, Joon Ha; Seo, Hyeon Kook; Ahn, Chi Won; Yuk, Jong Min

doi:10.1002/advs.201900264

Cited by 41 publications

(33 citation statements)

References 35 publications

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“…Figure 12j, m show the ex-situ SAED patterns of the full discharge and charge products. The results of ex-situ SAED patterns are [116] in accordance with the result of ex-situ XRD, confirming the discharge products are Na 2 S and Co and the charge product is Co 9 S 8 . Analysis of ex-situ XRD and SAED indicates a highly reversible conversion mechanism for the Co 9 S 8 during sodiation/desodiation.…”

Section: Sodium Storage Mechanism Investigated By In-situ and Ex-situsupporting

confidence: 74%

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Progress and Prospects of Transition Metal Sulfides for Sodium Storage

Yao

et al. 2020

Adv. Fiber Mater.

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Sodium-ion battery (SIB), one of most promising battery technologies, offers an alternative low-cost solution for scalable energy storage. Developing advanced electrode materials with superior electrochemical performance is of great significance for SIBs. Transition metal sulfides that emerge as promising anode materials have advantageous features particularly for electrochemical redox reaction, including high theoretical capacity, good cycling stability, easily-controlled structure and modifiable chemical composition. In this review, recent progress of transition metal sulfides based materials for SIBs is summarized by discussing the materials properties, advanced design strategies, electrochemical reaction mechanism and their applications in sodium-ion full batteries. Moreover, we propose several promising strategies to overcome the challenges of transition metal sulfides for SIBs, paving the way to explore and construct advanced electrode materials for SIBs and other energy storage devices.

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Section: Sodium Storage Mechanism Investigated By In-situ and Ex-situsupporting

confidence: 74%

“…On the other hand, Yuk et al revealed another sodiation mechanism of copper sulfide by ex-situ TEM and ex-situ HRTEM [116]. Figure 11i shows the structural evolution of CuS nanoplates upon charge/discharge.…”

Section: Sodium Storage Mechanism Investigated By In-situ and Ex-situmentioning

confidence: 99%

Progress and Prospects of Transition Metal Sulfides for Sodium Storage

Yao

et al. 2020

Adv. Fiber Mater.

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“…Based on the above results, the Na + -storage performance of the Cu 1.81 S MTs is superior to that of most of the previously reported Cu x S electrodes, 17,21,48,49,51,52 which can be ascribed to the fact that its unique triangular support structures accommodate volume changes during sodiation/desodiation, which effectively suppresses the pulverization of active materials ( Figure 5B). In addition, the hollow truss structure ensures the electrolyte rapid infiltration and shortens the diffusion length of electron/Na + ions for the acceleration of electrochemical kinetics as disclosed by electrochemical impedance spectroscopy (EIS) spectra (see Table S1 for details).…”

Section: Resultsmentioning

confidence: 60%

“…The electrode delivers an initial discharge/charge capacity of 563/487 mAh g À1 , corresponding to an initial Coulombic efficiency (CE) of 86.5%. The initial capacity loss of the MT electrode is much smaller than that of other Cu x S electrodes, 17,21,48,49,51,52 which may be due to the formation of a more stable solid electrolyte interphase film. Compared with the Cu x S HMCs, the Cu 1.81 S MTs illustrate a significant stability of 200 cycles at 0.1 A g À1 ( Figure 4C).…”

Section: Resultsmentioning

confidence: 89%

“…48 Meanwhile, the cathodic peaks at 1.47 V, 1.19 V, and 0.84 V are assigned to the multiple intercalation reactions of Na + ions into Cu 2Àx S lattices to form the intermediate phases Na x Cu y S z . 21,[49][50][51] Subsequently, a conversion reaction occurs in Na x Cu y S z to decompose into Na 2 S and Cu, corresponding to the cathodic peak at 0.41 V. For the anodic scan, the two peaks at 1.58 V and 2.12 V correspond to the conversion from Cu and Na 2 S to Na x Cu y S z and the deintercalation from Na x Cu y S z to Cu 2 S, 21,[49][50][51] respectively. These processes are further verified by in situ XRD and electrochemical measurements (see Figure S10 for details).…”

Section: Resultsmentioning

confidence: 99%

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A Selective Reduction Approach to Construct Robust Cu1.81S Truss Structures for High-Performance Sodium Storage

Shang

Huang

et al. 2020

Matter

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The practical application of transition metal sulfides as anodes for sodium-ion batteries has long been hindered by the design and fabrication of stable electrodes. Here, we introduce new concepts from architecture to design an electrode for rechargeable batteries with high rate capability and stable cycling performance. The well-designed Cu 1.81 S micro-truss structure delivers excellent performance. This work should provide new insights into a new generation of electrode structures and could be applied to the structural design of other batteries.

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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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Pulverization‐Tolerance and Capacity Recovery of Copper Sulfide for High‐Performance Sodium Storage

Cited by 41 publications

References 35 publications

Progress and Prospects of Transition Metal Sulfides for Sodium Storage

Progress and Prospects of Transition Metal Sulfides for Sodium Storage

A Selective Reduction Approach to Construct Robust Cu1.81S Truss Structures for High-Performance Sodium Storage

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

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