Synthesis of 3-dimensional interconnected porous Na3V2(PO4)3@C composite as a high-performance dual electrode for Na-ion batteries

Didwal, Pravin N.; Verma, Rakesh; Min, Chan-Woo; Park, Chan‐Jin

doi:10.1016/j.jpowsour.2018.12.018

Cited by 63 publications

(32 citation statements)

References 52 publications

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“…However, the increasing cost of Li due to the scarcity and uneven geographical distribution of Li resources may limit its sustainable application in the near future [5,6] . Consequently, next‐generation secondary batteries based on earth‐abundant elements, namely Na, K, and Mg, are considered promising alternatives to LIBs in future energy storage systems [7–15] . Among them, potassium‐ion batteries (PIBs) have recently attracted significant attention owing to their low cost, eco‐friendliness, and high energy density [5,6,12] .…”

Section: Introductionmentioning

confidence: 99%

Recent Progress in Electrolyte Development and Design Strategies for Next‐Generation Potassium‐Ion Batteries

Verma

Didwal

Hwang

et al. 2021

Batteries & Supercaps

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Rechargeable lithium‐ion batteries (LIBs) have attained tremendous success and are extensively used in a wide range of fields. However, due to the scarcity and uneven geographical distribution of Li resources, its price is steadily increasing, which may limit its sustainable application in the near future. Potassium‐ion batteries (PIBs) are promising alternatives to LIBs owing to the earth abundance, low cost, and eco‐friendliness of potassium, and high energy density of PIBs. Although the field of PIBs has seen significant progress in the recent years, some challenges remain that limit their application, such as the severe side reactions between the electrolyte and electrodes, which result in an unstable solid electrolyte interphase, and thus, a low coulombic efficiency. Hence, designing suitable electrolytes is necessary for the development of PIBs. This review summarises the current developments in PIB electrolytes and comprehensively discusses electrolyte design strategies for four major classes of electrolytes, namely non‐aqueous, aqueous, ionic liquid, and solid‐state electrolytes. In addition, the effects of the properties of each class of electrolyte are discussed in detail. Furthermore, ionic liquid electrolytes, an emerging class of electrolytes, are discussed in detail with respect to PIBs. Finally, several critical issues, challenges, and prospects of PIB electrolytes are discussed, and an outlook for the future research direction of PIBs is presented.

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Section: Introductionmentioning

confidence: 99%

Recent Progress in Electrolyte Development and Design Strategies for Next‐Generation Potassium‐Ion Batteries

Verma

Didwal

Hwang

et al. 2021

Batteries & Supercaps

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“…In terms of the cycling performance and rate performance, our full cell outperforms all the previously reported full cells in a symmetric conguration. [13][14][15][16]18,[27][28][29][30][31][32][33][34] This can be attributed to the excellent kinetics offered by the DME electrolyte in the NVP cathode and NVP anode. A Ragone plot comparing the symmetric NVP cell with different energy storage devices is shown in Fig.…”

Section: Resultsmentioning

confidence: 97%

High power Na₃V₂(PO₄)₃ symmetric full cell for sodium-ion batteries

et al. 2020

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“…As a comparison, the NVP@C and NVP@C‐300 exhibit rapid capacity fading and deliver inferior capacity along with the increasing charge/discharge rates to 40 C, although their specific capacities are a bit higher than hierarchical NVP@C⊂C with the rates ranging from 0.5 to 10 C due to the relatively high carbon content (Figure S6, Supporting Information). The cycling stability between NVP@C and NVP@C⊂C was further investigated to evaluate the effect of hierarchical carbon protection, as shown in Figure d. It can be observed that NVP@C exhibited a slightly higher initial specific capacity of 87.5 mAh −1 g −1 than that of latter, while the NVP@C⊂C possessed much better capacity retention of 91.97 % compared with that of NVP@C (78.9 %) after 5000 cycles at 5 C. More impressively, a high specific capacity of 64.61 mAh −1 g −1 still remained after 6000 cycles at the high rate of 20 C, corresponding to a capacity retention of 80.86 % (Figure e), which is outstanding compared with the state‐of‐the‐art values in previous literature (Table S1) . In addition, in order to explore the optimized calcination conditions of NVP@C⊂C, the influence of annealing temperatures on electrochemical performance was conducted (Figure S7, Supporting Information).…”

Section: Figurementioning

confidence: 99%

“…The NVP@C&Cd elivers the specific capacities of 89.6, 87.5, 85.9, 83.1, 82.7, 79.1, 75.6, 72.7, 69.2, 65.7, 62.3, 54, 49.4 and 46.1 mAh À1 g À1 at the rates of 0.5, 1, 2, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90 and 100 C, respectively,i ndicating an excellent capacity retention rate of 51.5 %f rom 0.5 to 100 C. When the current density was reverted to 0.5 C, ah igh specific capacityo f8 8.4 mAh À1 g À1 could be recovered, which is almost 100 %c apacity retention compared with the original value. [22,[44][45][46] In addition, in order to explore the optimized calcination conditions of NVP@C&C, the influence of annealing temperatures on electrochemical performance was conducted ( Figure S7, Supporting Information). Thec ycling stability between NVP@C and NVP@C&Cw as furtheri nvestigatedt oe valuate the effect of hierarchical carbon protection, as shown in Figure 4d.Itcan be observed that NVP@Cexhibited as lightly higher initial specific capacity of 87.5 mAh À1 g À1 than that of latter,w hile the NVP@C&Cp ossessed much better capacity retention of 91.97 %c ompared with that of NVP@C (78.9 %) after 5000 cycles at 5C.M ore impressively,ah igh specific capacity of 64.61 mAh À1 g À1 still remained after 6000 cycles at the high rate of 20 C, corresponding to ac apacity retention of 80.86 % ( Figure 4e), which is outstanding compared with the state-of-the-art values in previous literature( Ta bleS1).…”

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Designed One‐Pot Strategy for Dual‐Carbon‐Protected Na₃V₂(PO₄)₃ Hybrid Structure as High‐Rate and Ultrastable Cathode for Sodium‐Ion Batteries

Peng

et al. 2019

Chemistry A European J

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Sodium-ion batterieshave attracted tremendous attention due to their much lower cost and similarw orking principle compared with lithium-ion batteries, which have been invited great expectation as energy storaged evices in grid-level applications.T he sodium superionic conductor Na 3 V 2 (PO 4 ) 3 has been considered as apromising cathodec andidate;h owever,i ts intrinsic low electronic conductivity results in poor rate performance and unsatisfactory cycling performance, which severely impedesi ts potential for practical applications. Herein, we developed af acile one-pots trategyt oc onstruct dual carbon-protected hybrid structure composed of carbon coated Na 3 V 2 (PO 4 ) 3 nanoparticles embedded with carbon matrix with excellent rate performance, superior cycling stability and ultralong lifespan.S pecifically,i tc an deliver an outstandingr ate performance with a5 1.5 %c apacity retention from 0.5 to 100 Ca nd extraordinary cycling stability of 80.86 %c apacity retention after 6000 cycles at the high rate of 20 C. The possible reasonsf or the enhanced performance could be understooda st he synergistic effects of the strengthened robusts tructure, facilitated charge transferk inetics, and the mesoporous nature of the Na 3 V 2 (PO 4 ) 3 hybrid structure. This work provides ac ost-effective strategyt oe ffectively optimize the electrochemical performance of aN a 3 V 2 (PO 4 ) 3 cathode, which could contribute to push forwardt he advance of its practical applications.The constantly increasing energyc onsumption based on traditional fossil fuels has compelled the efforts on the exploitation of renewable energy resources, such as solar and wind. [1][2][3] However,t he intrinsic drawbacks of intermittencya nd regional disparity of the sustainable energy techniques make it necessary to store the electricity at peak times in order to reach a stablea nd constant output when needed. As ac onsequence, highlye fficient yet low-cost energy storage devices need to be developed in order to meet the requirementf or grid-level applications. [4][5][6] Although lithium-ion batteries (LIBs) have been considered as the most suitable powers ourcesf or consumable electronicsa nd/ore lectric vehicles after their successful commercialization in the 1990s, the rapidly increasing price of Li as ar esource has inevitably raised the issue of unaffordable cost when appliedi nl arge-scale energy storages ystems. Recently, sodiumi on batteries( SIBs) have received tremendous attention due to their much lower cost and similarworkingprinciple compared with thoseo fL IBs, which have been suggested as promising candidates for energy storagei ng rid-level applications. [7][8][9][10] However,t here are remaining challenges for practical applications of SIBs, such as the relativelyl ow power/energy density and unsatisfactory cycle life. [11] Therefore, it is always imperative to exploit high performance electrode materials with excellentr ate performance and cycling stability forS IBs, in order to meet the requiremento fc ommercialization. [12] More...

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Synthesis of 3-dimensional interconnected porous Na3V2(PO4)3@C composite as a high-performance dual electrode for Na-ion batteries

Cited by 63 publications

References 52 publications

Recent Progress in Electrolyte Development and Design Strategies for Next‐Generation Potassium‐Ion Batteries

Recent Progress in Electrolyte Development and Design Strategies for Next‐Generation Potassium‐Ion Batteries

High power Na₃V₂(PO₄)₃ symmetric full cell for sodium-ion batteries

Designed One‐Pot Strategy for Dual‐Carbon‐Protected Na₃V₂(PO₄)₃ Hybrid Structure as High‐Rate and Ultrastable Cathode for Sodium‐Ion Batteries

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Synthesis of 3-dimensional interconnected porous Na3V2(PO4)3@C composite as a high-performance dual electrode for Na-ion batteries

Cited by 63 publications

References 52 publications

Recent Progress in Electrolyte Development and Design Strategies for Next‐Generation Potassium‐Ion Batteries

Recent Progress in Electrolyte Development and Design Strategies for Next‐Generation Potassium‐Ion Batteries

High power Na3V2(PO4)3 symmetric full cell for sodium-ion batteries

Designed One‐Pot Strategy for Dual‐Carbon‐Protected Na3V2(PO4)3 Hybrid Structure as High‐Rate and Ultrastable Cathode for Sodium‐Ion Batteries

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High power Na₃V₂(PO₄)₃ symmetric full cell for sodium-ion batteries

Designed One‐Pot Strategy for Dual‐Carbon‐Protected Na₃V₂(PO₄)₃ Hybrid Structure as High‐Rate and Ultrastable Cathode for Sodium‐Ion Batteries