Ultrathin Nanoribbons of in Situ Carbon-Coated V3O7·H2O for High-Energy and Long-Life Li-Ion Batteries: Synthesis, Electrochemical Performance, and Charge–Discharge Behavior

Liu, Pengcheng; Kan, Biao; Zhu, Kongjun; Xu, Yuan; Gao, Yanfeng; Luo, Hongjie; Li, Lü; Wang, Jing; Liu, Jinsong; Tai, Guòan

doi:10.1021/acsami.7b01504

Cited by 61 publications

(25 citation statements)

References 67 publications

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“…However, it should be noted that although the cycling performance was improved, the capacity was decreased. In our recent work, [31] to further improve the cycling performance of V 3 O 7 ·H 2 O, a in situ carbon coating method was proposed to synthesize the ultrathin V 3 O 7 ·H 2 O@C nanoribbons based on HTMM for just 1 h. As-prepared V 3 O 7 ·H 2 O@C nanoribbons exhibited the improved electrochemical performance: the capacity was up to 319 mA h g −1 at 100 mA g −1 , a capacity of 262 mA h g −1 can be delivered at 500 mA g −1 with a capacity retention of 94% after 100 cycles, and especially their energy density was up to 800 W h kg −1 . Figure 2c, the crystal structures of V 3 O 7 ·H 2 O are basically analogous in terms of the edge-sharing VO 6 octahedral units forming zigzag chains, which are connected by the chains of edge-sharing VO 5 trigonal bi-pyramids by vertex sharing, then the joint chains of VO 6 -VO 5 build a V 3 O 8 layer.…”

Section: Low-dimensional Nanomaterialsmentioning

confidence: 93%

“…Among various vanadium-based oxides, V 2 O 5 have attracted the most attention. [46] (326, 80% after 100 at 500) steel-supported V 6 O 13 [75] (≈300, ≈83 after 100 at 500) [31] (319, 94% after 100 at 500) NA NA VO 2 (B) VO 2 (B)@C nanosheets [76] (160, 78% after 50 at 100) VO 2 (B)@C-SLMBs [44] (206, 104% after 1000 at 1000) GVG [77] (421, 94% after 1500 at 18000) [78] (171, 48% after 60 at ≈50) box-in-box V 2 O 3 /C [79] (794, 116% after 1200 at 1000) NA [81,82] During discharging from 4.0 to 3.4 V: 0.…”

Section: Omentioning

confidence: 99%

“…The interlayer-expanded V 6 O 13 nanosheets were synthesized to improve the cycling performance. [30,31,[125][126][127][128][129] For example, a PEO/V 3 O 7 ·H 2 O nanobelts composite was synthesized by hydrothermal method for 48 h. [129] The initial capacity of this kind of composite was 297 mA h g −1 , but the capacity decreased rapidly to ≈170 mA h g −1 after 40 cycles, and the capacity retention was 58%. It can also deliver a stable capacity when fabricated as a full cell.…”

Section: Low-dimensional Nanomaterialsmentioning

confidence: 99%

“…These have been a lot of applications of vanadium-based oxides on electrode materials of LIBs and NIBs. [30,31] It was found that Li 3 VO 4 was a promising insertion anode material for LIBs with a low and safe discharge voltage (≈0.75 V vs Li/Li + in average), and delivered a large capacity (≈323 mA h g −1 ). [28] As cathode materials of NIBs, single-crystalline bilayered V 2 O 5 nanobelts can deliver a high capacity of 229 mA h g −1 at 80 mA g −1 .…”

mentioning

confidence: 99%

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Recent Progress in the Applications of Vanadium‐Based Oxides on Energy Storage: from Low‐Dimensional Nanomaterials Synthesis to 3D Micro/Nano‐Structures and Free‐Standing Electrodes Fabrication

Liu

Zhu

Gao

et al. 2017

Advanced Energy Materials

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167

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IntroductionWith the economic, science and technology increasing at an amazing speed, energy has become one of the most important issues in the 21 st century. In addition, the supply of fossil With revolutionary electric vehicles and the smart grid fast developing, more advanced energy storage technologies become quite crucial issues. Li-ion batteries (LIBs) and Na-ion batteries (NIBs) are considered as the most promising electrochemical energy storage technologies. Low-dimensional nano-structural electrode materials can greatly increase the specific capacity, but they still suffer from poor cycling and rate performances due to their serious self-aggregations. Constructing 3D structures, such as micro/ nano-structures and free-standing electrodes, is a quite promising method to address the above issues. Such 3D structures can simultaneously avoid the disadvantages of low-dimensional nanomaterials, and preserve their advantages. As one group of promising high-capacity and low-cost electrode materials, vanadium-based oxides have exhibited an quite attractive electrochemical performance for energy storage applications in many novel works. However, their systematic reviews are quite limited, which is disadvantageous to their further development. Herein, this article provides an overview of vanadium-based oxides in the applications of LIBs and NIBs by focusing mainly on the aspect from low-dimensional nanomaterials synthesis to 3D micro/nano-structures and free-standing electrodes fabrication. Moreover, a feasible strategy to controllably fabricate the 3D micro/nano-structure for the whole vanadium-based oxides family is presented. Furthermore, and importantly, a quite promising solution method for the practical commercialized applications of vanadium oxides cathode materials in the future is proposed, i.e., fabricating the "vanadium oxides-based cathode/solid electrolyte/Li metal anode-type" all solid-state secondary-ion batteries.

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Section: Low-dimensional Nanomaterialsmentioning

confidence: 93%

Section: Omentioning

confidence: 99%

Section: Low-dimensional Nanomaterialsmentioning

confidence: 99%

mentioning

confidence: 99%

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Recent Progress in the Applications of Vanadium‐Based Oxides on Energy Storage: from Low‐Dimensional Nanomaterials Synthesis to 3D Micro/Nano‐Structures and Free‐Standing Electrodes Fabrication

Liu

Zhu

Gao

et al. 2017

Advanced Energy Materials

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167

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“…[37] During the coloration process (0.2 V), the high valence state V 5+ was partially reduced to V 4+ and the atomic ratio of V 5+ /V 4+ decreased to 0.32 (Table S1, Supporting Information). [37] During the coloration process (0.2 V), the high valence state V 5+ was partially reduced to V 4+ and the atomic ratio of V 5+ /V 4+ decreased to 0.32 (Table S1, Supporting Information).…”

Section: Wwwadvopticalmatdementioning

confidence: 99%

Electrochromic Battery Displays with Energy Retrieval Functions Using Solution‐Processable Colloidal Vanadium Oxide Nanoparticles

Zhang

Al‐Hussein

et al. 2019

Advanced Optical Materials

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for developing bistable displays due to their zero-energy consumption while maintaining a colored or colorless state. [3] However, operation of traditional electrochromic displays requires external voltages to trigger the coloration/bleaching processes, which makes the traditional electrochromic displays far from a netzero energy-consumption technology. The majority of the current electrochromic display research has focused on developing nanostructure electrochromic materials for fast switchings [4,5] without paying attention to how to reduce the consumed energy of the electrochromic displays.Recently, we developed a promising Zn-based electrochromic battery technology for smart windows. [6,7] The electrochromic battery exhibits self-coloration behaviors and eliminates the external voltage requirement for triggering the coloration process. The aqueous compatible Zn anode implements a much lower charged/bleached voltage for the electrochromic battery compared to the Li-and Al-based electrochromic batteries. [8][9][10] The lower charged/bleached potential indicates a lower energy consumption during the bleaching process. As such, the Zn-based aqueous electrochromic battery platform is an energy-efficient technology for reducing the energy consumption of electrochromic devices. To date, no reports exist on the utilization of electrochromic battery systems for developing energy-efficient electrochromic displays.Electrochromic materials play an important role in the development of electrochromic battery displays. Transition metal oxides (TMOs) have shown excellent electrochromic properties due to their remarkable multivalence states and the corresponding color evolutions. [11][12][13][14][15] Among the TMOs, vanadium oxide is considered the most promising material for electrochromic displays because of its multicolor behaviors. [16][17][18] However, the low electrical conductivity, significant volume expansion during cycling, and the slow reaction kinetics of bulk vanadium oxide prevent its widespread use. [19,20] In recent years, nanosized vanadium oxides have been studied to mediate these drawbacks because nanostructures provide abundant active sites on the surface and shorten the diffusion paths of ions. [20] Techniques, such as electrodeposition, [19] Electrochromic displays have attracted increased attention owing to their reversible switch of multicolors. However, the external voltage requirement for triggering the color switching makes them far from an optimum energyefficient technology. The newly developed electrochromic batteries eliminate the energy consumption for coloration while they can retrieve the consumed energy for bleaching. Such features make the electrochromic battery technology the most promising technology for energy-efficient electrochromic displays. Here, a scalable method to synthesize colloidal V 3 O 7 nanoparticles is presented, which is compatible with solution-process techniques for aqueous Zn-V 3 O 7 electrochromic battery displays. The Zn-V 3 O 7 electrochromic battery display shows an ...

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Synergetic Nitrogen‐Rich Nanocarbon Decoration and Metal Intercalation Enabled Low‐Crystalline V₃O₇ Hybrids for Boosting Capacitive Sodium Capture

Yang,

Sun,

Zhang

et al. 2024

Adv Funct Materials

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Faradaic capacitive deionization (FCDI) with attractive ion‐capture capacity, outstanding durability, and potential compatibility in high‐salinity water has been recognized as the robust alternative to address the alarming freshwater scarcity. The further innovation of boosting electrode materials is the indispensable requisite for highly efficient FCDI application. Herein, a low‐crystalline nitrogen‐doped carbon quantum dots modified Mg2+‐pillar preintercalated V3O7 (i.e., NCQDs/Mg‐V3O7) heterostructure is assembled via an ingenious one‐spot hydrothermal avenue, and is investigated as the advanced FCDI electrode for desalination application. Taking advantages of the synergic effect of unique microstructure, improved electronic conductivity, and exceptional structural durability, the NCQDs/Mg‐V3O7 electrode delivers an admirable gravimetric adsorption capacity of 54.32 mg g−1 in a NaCl solution of 1500 mg L−1 and attractive cyclic durability. Further, density functional theory calculations verify the intense interface electron coupling interaction between tri‐components, enabling the significantly promoting Na+ capture capability. The synergy removal mechanism is clarified by ex‐situ X‐ray photoelectron spectroscopy and in‐situ Raman tests. Additionally, the average removal efficiency of hybrid electrode attains 93.75% in the simulated wastewater comprising the NaCl of 50 mg L−1 and diverse metal nitrates from 10 to 100 mg L−1 for each, certifying the great prospects for practical wastewater treatment.

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Ultrathin Nanoribbons of in Situ Carbon-Coated V₃O₇·H₂O for High-Energy and Long-Life Li-Ion Batteries: Synthesis, Electrochemical Performance, and Charge–Discharge Behavior

Cited by 61 publications

References 67 publications

Recent Progress in the Applications of Vanadium‐Based Oxides on Energy Storage: from Low‐Dimensional Nanomaterials Synthesis to 3D Micro/Nano‐Structures and Free‐Standing Electrodes Fabrication

Recent Progress in the Applications of Vanadium‐Based Oxides on Energy Storage: from Low‐Dimensional Nanomaterials Synthesis to 3D Micro/Nano‐Structures and Free‐Standing Electrodes Fabrication

Electrochromic Battery Displays with Energy Retrieval Functions Using Solution‐Processable Colloidal Vanadium Oxide Nanoparticles

Synergetic Nitrogen‐Rich Nanocarbon Decoration and Metal Intercalation Enabled Low‐Crystalline V₃O₇ Hybrids for Boosting Capacitive Sodium Capture

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Ultrathin Nanoribbons of in Situ Carbon-Coated V3O7·H2O for High-Energy and Long-Life Li-Ion Batteries: Synthesis, Electrochemical Performance, and Charge–Discharge Behavior

Cited by 61 publications

References 67 publications

Recent Progress in the Applications of Vanadium‐Based Oxides on Energy Storage: from Low‐Dimensional Nanomaterials Synthesis to 3D Micro/Nano‐Structures and Free‐Standing Electrodes Fabrication

Recent Progress in the Applications of Vanadium‐Based Oxides on Energy Storage: from Low‐Dimensional Nanomaterials Synthesis to 3D Micro/Nano‐Structures and Free‐Standing Electrodes Fabrication

Electrochromic Battery Displays with Energy Retrieval Functions Using Solution‐Processable Colloidal Vanadium Oxide Nanoparticles

Synergetic Nitrogen‐Rich Nanocarbon Decoration and Metal Intercalation Enabled Low‐Crystalline V3O7 Hybrids for Boosting Capacitive Sodium Capture

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Ultrathin Nanoribbons of in Situ Carbon-Coated V₃O₇·H₂O for High-Energy and Long-Life Li-Ion Batteries: Synthesis, Electrochemical Performance, and Charge–Discharge Behavior

Synergetic Nitrogen‐Rich Nanocarbon Decoration and Metal Intercalation Enabled Low‐Crystalline V₃O₇ Hybrids for Boosting Capacitive Sodium Capture