Layered VOPO<sub>4</sub> as a Cathode Material for Rechargeable Zinc-Ion Battery: Effect of Polypyrrole Intercalation in the Host and Water Concentration in the Electrolyte

Verma, Vivek; Kumar, Sonal; Manalastas, William; Zhao, Jianwei; Chua, Rodney; Meng, Shize; Kidkhunthod, Pinit; Srinivasan, Madhavi

doi:10.1021/acsaem.9b01632

Cited by 101 publications

(118 citation statements)

References 45 publications

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“…Recently, two-dimensional (2D) layer electrodes have shown the promising electrochemical property due to their unique 2D ion transport corridor, short ion diffusion distance and adjustable interlayer space, which are beneficial to promote the Na-ion insertion/extraction reactions (Huang et al, 2014;Shi et al, 2019;Verma et al, 2019). Among them, 2D hydrated vanadium oxyphosphate (VOPO 4 •2H 2 O) has received considerable attention as the promising cathode materials for SIBs because of its high redox reaction potential (∼3.5 V), high theoretical specific capacity (166 mAh g −1 ), and various valences reactions (e.g., V 5+…”

Section: Introductionmentioning

confidence: 99%

VOPO4⋅2H2O Nanosheet Cathode for Enhanced Sodium Storage

et al. 2020

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Na-ion batteries (SIBs) are anticipated to capture a broad development space in the field of large-scale energy storage due to the abundant sodium resources. High-performance cathode materials are very critical. VOPO 4 •2H 2 O with a two-dimensional (2D) layered structure is a very promising candidate for SIBs because of its high working voltage and theoretical specific capacity. Herein, a simple one-step reflux method is designed to fabricate a cathode of VOPO 4 •2H 2 O nanosheets. It exhibits a high average operating potential of ∼3.5 V, remarkable specific capacity (e.g., 135 mAh g −1 at 0.05 C), favorable high current charge-discharge ability (e.g., 58 mAh g −1 even at 20 C) as well as extralong cyclability (e.g., 0.026% capacity fading rate for per cycle at 20 C during 1000 cycles). The kinetic analysis implies that the superior sodium storage performance is mainly benefiting from the advantages of unique nanosheet structure, accelerating the rapid Na-ion diffusion.

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Section: Introductionmentioning

confidence: 99%

VOPO4⋅2H2O Nanosheet Cathode for Enhanced Sodium Storage

et al. 2020

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“…[ 33,38 ] The high‐voltage operability of VOPO 4 in ZMBs is recently receiving attention owing to the presence of the phosphate group linked to the vanadium‐ion center, which is reported to expand the cation intercalation voltage (due to inductive effect) compared to oxides. [ 40–42 ] Here, the synthesis of VOPO 4 is performed using a simple reflux method. The scheme adopted for the synthesis of VOPO 4 is presented in Figure S2 (Supporting Information).…”

Section: Figurementioning

confidence: 99%

“…2H 2 O phase. [ 40,43 ] Field emission scanning electron microscope (FESEM) images of the as‐synthesized VOPO 4 . 2H 2 O samples are shown in Figure 1d,e).…”

Section: Figurementioning

confidence: 99%

“…The peaks at 519.1 (V2p 3/2 ) and 526.5 eV (V2p 1/2 ) correspond to the V 5+ oxidation state, and if one closely observes, a small quantity of V 4+ can also be observed (peak at 517.2 eV). [ 40,44 ] Similarly, the peak at 134.2 eV is associated with the P2p energy level indicating a pentavalent tetra‐bonded P. [ 44 ] The peak originating from the oxygen O2p energy level at 531.9 eV is also visible. [ 45 ]…”

Section: Figurementioning

confidence: 99%

“…The cell displayed a high specific capacity of 78 mAh g −1 (at 0.05 Ag −1 ), which is comparable with several other nonaqueous liquid electrolyte‐based ZMBs (summarized in Table S2, Supporting Information). [ 19,28,29,40,50–52 ] At the same current density of 0.05 Ag −1 , the cell delivers an E av of 1.2 V with a specific energy density of 96 Wh kg −1 (calculation of E av is provided in Figure S13 (Supporting Information) followed by relevant explanations). The specific energy density values at other current densities are also presented in Figure 4b.…”

Section: Figurementioning

confidence: 99%

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An In Situ Cross‐Linked Nonaqueous Polymer Electrolyte for Zinc‐Metal Polymer Batteries and Hybrid Supercapacitors

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This work reports the facile synthesis of nonaqueous zinc‐ion conducting polymer electrolyte (ZIP) membranes using an ultraviolet (UV)‐light‐induced photopolymerization technique, with room temperature (RT) ionic conductivity values in the order of 10−3 S cm−1. The ZIP membranes demonstrate excellent physicochemical and electrochemical properties, including an electrochemical stability window of >2.4 V versus Zn|Zn2+ and dendrite‐free plating/stripping processes in symmetric Zn||Zn cells. Besides, a UV‐polymerization‐assisted in situ process is developed to produce ZIP (abbreviated i‐ZIP), which is adopted for the first time to fabricate a nonaqueous zinc‐metal polymer battery (ZMPB; VOPO4|i‐ZIP|Zn) and zinc‐metal hybrid polymer supercapacitor (ZMPS; activated carbon|i‐ZIP|Zn) cells. The VOPO4 cathode employed in ZMPB possesses a layered morphology, exhibiting a high average operating voltage of ≈1.2 V. As compared to the conventional polymer cell assembling approach using the ex situ process, the in situ process is simple and it enhances the overall electrochemical performance, which enables the widespread intrusion of ZMPBs and ZMPSs into the application domain. Indeed, considering the promising aspects of the proposed ZIP and its easy processability, this work opens up a new direction for the emergence of the zinc‐based energy storage technologies.

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Interlayer Chemistry of Layered Electrode Materials in Energy Storage Devices

Zhang

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et al. 2020

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With the constant focus on energy storage devices, layered materials are ideal electrodes for the new generation of highly efficient secondary ion batteries and supercapacitors due to their flexible 2D structures and high theoretical capacities. However, the small interlayer distances in layered electrode materials and the strong Columbic interactions between the working ions and host lattice anions cause slow ion diffusion. In addition, structural collapse during repeated ion insertion and extraction reduces the cycling lifetime. As such, interlayer engineering strategies are effective approaches to optimize ion transmission kinetics and structural integrity. In view of the latest research on the interlayer engineering of layered materials, this review will discuss useful strategies to improve electrode performance. The synthetic strategies, characterization techniques, and effects of interlayer‐engineered layered materials, including metal oxides, metal sulfides, carbonous materials, and MXenes, are discussed in detail. The future outlook and challenges for interlayer engineering are also presented, which may pave the way for the development of new layered materials.

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Layered VOPO₄ as a Cathode Material for Rechargeable Zinc-Ion Battery: Effect of Polypyrrole Intercalation in the Host and Water Concentration in the Electrolyte

Cited by 101 publications

References 45 publications

VOPO4⋅2H2O Nanosheet Cathode for Enhanced Sodium Storage

VOPO4⋅2H2O Nanosheet Cathode for Enhanced Sodium Storage

An In Situ Cross‐Linked Nonaqueous Polymer Electrolyte for Zinc‐Metal Polymer Batteries and Hybrid Supercapacitors

Interlayer Chemistry of Layered Electrode Materials in Energy Storage Devices

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Layered VOPO4 as a Cathode Material for Rechargeable Zinc-Ion Battery: Effect of Polypyrrole Intercalation in the Host and Water Concentration in the Electrolyte

Cited by 101 publications

References 45 publications

VOPO4⋅2H2O Nanosheet Cathode for Enhanced Sodium Storage

VOPO4⋅2H2O Nanosheet Cathode for Enhanced Sodium Storage

An In Situ Cross‐Linked Nonaqueous Polymer Electrolyte for Zinc‐Metal Polymer Batteries and Hybrid Supercapacitors

Interlayer Chemistry of Layered Electrode Materials in Energy Storage Devices

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Product

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Layered VOPO₄ as a Cathode Material for Rechargeable Zinc-Ion Battery: Effect of Polypyrrole Intercalation in the Host and Water Concentration in the Electrolyte