Boosting Zn-Ion Storage Performance of Bronze-Type VO₂ via Ni-Mediated Electronic Structure Engineering

Abstract: Aqueous rechargeable zinc-ion batteries are emerging as attractive alternatives for postlithium-ion batteries. However, their electrochemical performances are restricted by the narrow working window of materials in aqueous electrolytes. Herein, Ni-mediated VO 2 -B nanobelt ((Ni)VO 2 ) has been designed to optimize the intrinsic electronic structure of VO 2 -B, and thus achieve much more enhanced zinc-ion storage. Specifically, the Zn/(Ni)VO 2 battery yields good rate capability (182.0 mAh g -1 at 5 A g -1 ) wi… Show more

“…The ex situ Raman study during the charging/discharging process shows the appearance of six peaks at 319.15, 352.07, 581.91, 766.21, 866.09, and 1035.21 cm –1 . The peaks at 766.21 and 1035.21 cm –1 are attributed to the stretching vibration of V–O and V–O–V modes, respectively. , The additional peaks at 300–500 and 866.09 cm –1 are ascribed to the formation of Zn 3 (OH) 2 V 2 O 7 ·2H 2 O and Zn x (OTf) y (OH) 2 x − y · n H 2 O phases as reported in the literature. ,, Furthermore, the electrochemical performance of the Zn//MVS2 device was measured in the 0.1 M H 2 SO 4 ACN/water hybrid electrolyte as shown in Figure S15. The device exhibits 53.52 mA h g –1 specific capacity at 0.2 A g –1 current density.…”

“… ,, Another crystalline phase is located at 2θ ≈ 23.85° for the orthorhombic sulfur. The orthorhombic sulfur peak repeatedly appears and disappears during the discharging/charging process of the electrode, indicating an additional capacity contribution due to the reversible in situ anodization of sulfur. ,,,− Therefore, a partial conversion of VS 4 to Zn 3 (OH) 2 V 2 O 7 ·2H 2 O and orthorhombic sulfur is observed during the discharging process with water and Zn 2+ ion reactants. Furthermore, the poor crystallinity of the Zn x (OTf) y (OH) 2 x − y · n H 2 O phase is indexed to the 2θ ≈ 34.87 and 48.35° plane, and the peaks frequently appear/disappear with potential cycling.…”

“…3 (OH) 2 V 2 O 7 •2H 2 O and Zn x (OTf) y (OH) 2x−y •nH 2 O phases as reported in the literature 46,49,51. Furthermore, the electrochemical performance of the Zn//MVS2 device was measured in the 0.1 M H 2 SO 4 ACN/water hybrid electrolyte as shown in FigureS15.…”

“…Furthermore, the poor crystallinity of the Zn x (OTf) y (OH) 2x−y •nH 2 O phase is indexed to the 2θ ≈ 34.87 and 48.35°plane, and the peaks frequently appear/ disappear with potential cycling. This reversible phenomenon indicates that the H + and Zn 2+ ion insertion/extraction process occurs simultaneously 16,21,46,49. During the initial discharging, a large number of protons are inserted into the cathode, and the hydroxyl groups in the electrolyte increase, resulting in the formation of the Zn x (OTf) y (OH) 2x−y •nH 2 O crystal phase.…”

A Reversible Anodizing Strategy in a Hybrid Electrolyte Zn-Ion Battery through Structural Modification of a Vanadium Sulfide Cathode

“…The ex situ Raman study during the charging/discharging process shows the appearance of six peaks at 319.15, 352.07, 581.91, 766.21, 866.09, and 1035.21 cm –1 . The peaks at 766.21 and 1035.21 cm –1 are attributed to the stretching vibration of V–O and V–O–V modes, respectively. , The additional peaks at 300–500 and 866.09 cm –1 are ascribed to the formation of Zn 3 (OH) 2 V 2 O 7 ·2H 2 O and Zn x (OTf) y (OH) 2 x − y · n H 2 O phases as reported in the literature. ,, Furthermore, the electrochemical performance of the Zn//MVS2 device was measured in the 0.1 M H 2 SO 4 ACN/water hybrid electrolyte as shown in Figure S15. The device exhibits 53.52 mA h g –1 specific capacity at 0.2 A g –1 current density.…”

“… ,, Another crystalline phase is located at 2θ ≈ 23.85° for the orthorhombic sulfur. The orthorhombic sulfur peak repeatedly appears and disappears during the discharging/charging process of the electrode, indicating an additional capacity contribution due to the reversible in situ anodization of sulfur. ,,,− Therefore, a partial conversion of VS 4 to Zn 3 (OH) 2 V 2 O 7 ·2H 2 O and orthorhombic sulfur is observed during the discharging process with water and Zn 2+ ion reactants. Furthermore, the poor crystallinity of the Zn x (OTf) y (OH) 2 x − y · n H 2 O phase is indexed to the 2θ ≈ 34.87 and 48.35° plane, and the peaks frequently appear/disappear with potential cycling.…”

“…3 (OH) 2 V 2 O 7 •2H 2 O and Zn x (OTf) y (OH) 2x−y •nH 2 O phases as reported in the literature 46,49,51. Furthermore, the electrochemical performance of the Zn//MVS2 device was measured in the 0.1 M H 2 SO 4 ACN/water hybrid electrolyte as shown in FigureS15.…”

“…Furthermore, the poor crystallinity of the Zn x (OTf) y (OH) 2x−y •nH 2 O phase is indexed to the 2θ ≈ 34.87 and 48.35°plane, and the peaks frequently appear/ disappear with potential cycling. This reversible phenomenon indicates that the H + and Zn 2+ ion insertion/extraction process occurs simultaneously 16,21,46,49. During the initial discharging, a large number of protons are inserted into the cathode, and the hydroxyl groups in the electrolyte increase, resulting in the formation of the Zn x (OTf) y (OH) 2x−y •nH 2 O crystal phase.…”

A Reversible Anodizing Strategy in a Hybrid Electrolyte Zn-Ion Battery through Structural Modification of a Vanadium Sulfide Cathode

“…Recently, manganese oxides, − Prussian blue analogues, , spinel oxides, , organic materials, , and vanadium-based compounds − have been studied as potential positive electrodes for RZBs. Among them, vanadium oxides hold great prospects because of their affordability, multi-electron redox reactions, and large ion transfer channels. − …”

Long-Life Zinc/Vanadium Pentoxide Battery Enabled by a Concentrated Aqueous ZnSO₄ Electrolyte with Proton and Zinc Ion Co-Intercalation

Theoretical Fundamentals of Aqueous Zinc‐Ion Batteries