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1. Structural impact of Zn-insertion into monoclinic V ₂ (PO ₄ ) ₃ : implications for Zn-ion batteries

   https://doi.org/10.1039/C9TA00716D  

   Park, Min Je; Yaghoobnejad Asl, Hooman; Therese, Soosairaj; Manthiram, Arumugam (March 2019, Journal of Materials Chemistry A)

   The zinc-ion battery (ZIB) has been a system of particular interest in the research community as a possible alternative to lithium-ion batteries (LIB), and much work has been devoted to finding a suitable host material. In this article, monoclinic V 2 (PO 4 ) 3 is investigated as a host material for reversible insertion of Zn 2+ . Initial chemical assessment via a facile microwave-assisted chemical insertion method indicates the possibility of Zn 2+ insertion into the host. Electrochemical assessment, however, exhibits a significant capacity fade. In-depth analysis on the average and local structure of Li 3 V 2 (PO 4 ) 3 , the empty host V 2 (PO 4 ) 3 , and the Zn-inserted V 2 (PO 4 ) 3 reveals that heavy distortion is induced upon Zn 2+ insertion into the V 2 (PO 4 ) 3 framework, which is believed to be a result of a strong host–guest interaction jeopardizing the structural integrity. This is further supported by the dissolution of most of the material during the chemical oxidation of the Zn-inserted V 2 (PO 4 ) 3 . The underlying structural inadequacy poses difficulties for monoclinic V 2 (PO 4 ) 3 to be a viable reversible host for Zn-ion batteries. This work suggests that not only the electrostatic repulsions of multivalent ions in a structure during diffusion, but also the structural stability of the host upon insertion of multivalent ions, must be considered for a better design of suitable host materials for multivalent-ion batteries. 

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2. Recent advances in developing organic electrode materials for multivalent rechargeable batteries

   https://doi.org/10.1039/d0ee02111c  

   Qin, Kaiqiang; Huang, Jinghao; Holguin, Kathryn; Luo, Chao (November 2020, Energy & Environmental Science)

   null (Ed.)

   Due to the low cost and abundance of multivalent metallic resources (Mg/Al/Zn/Ca), multivalent rechargeable batteries (MRBs) are promising alternatives to Li-ion and Pb-acid batteries for grid-scale stationary energy storage applications. However, the high performance of inorganic electrode materials in Li-ion batteries does not extend to MRBs, because the high charge density of multivalent cations dramatically reduces their diffusivity in the crystal lattice of inorganic materials. To achieve high-performance MRBs, organic electrode materials (OEMs) with abundant structural diversity and high structural tunability offer opportunities. This review presents an overview of the state-of-the-art OEMs in MRBs, including non-aqueous rechargeable Mg/Al/Zn and aqueous rechargeable Mg/Al/Zn/Ca batteries. The advantages, challenges, development, mechanism, structure, and performance of OEMs in MRBs are discussed in detail. To provide a comprehensive and thorough understanding of OEMs in MRBs, the correlation between molecular structure and electrochemical behavior is also summarized and discussed. This review offers insights for the rational structure design and performance optimization of advanced OEMs in MRBs. 

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3. Molybdenum Vanadium Oxides as Intercalation Hosts for Chloroaluminate Anions

   https://doi.org/10.3390/batteries9020092  

   Bhimani, Kevin; Lakhnot, Aniruddha Singh; Sharma, Shyam; Sharma, Mukul; Panchal, Reena A; Mahajani, Varad; Koratkar, Nikhil (February 2023, Batteries)

   Driven by the cost and scarcity of Lithium resources, it is imperative to explore alternative battery chemistries such as those based on Aluminum (Al). One of the key challenges associated with the development of Al-ion batteries is the limited choice of cathode materials. In this work, we explore an open-tunnel framework-based oxide (Mo3VOx) as a cathode in an Al-ion battery. The orthorhombic phase of molybdenum vanadium oxide (o-MVO) has been tested previously in Al-ion batteries but has shown poor coulombic efficiency and rapid capacity fade. Our results for o-MVO are consistent with the literature. However, when we explored the trigonal polymorph of MVO (t-MVO), we observe stable cycling performance with much improved coulombic efficiency. At a charge–discharge rate of ~0.4C, a specific capacity of ~190 mAh g−1 was obtained, and at a higher rate of 1C, a specific capacity of ~116 mAh g−1 was achieved. We show that differences in synthesis conditions of t-MVO and o-MVO result in significantly higher residual moisture in o-MVO, which can explain its poor reversibility and coulombic efficiency due to undesirable water interactions with the ionic liquid electrolyte. We also highlight the working mechanism of MVO || AlCl3–[BMIm]Cl || Al to be different than reported previously. 

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4. Reversible and rapid calcium intercalation into molybdenum vanadium oxides

   https://doi.org/10.1073/pnas.2205762119  

   Lakhnot, Aniruddha S.; Bhimani, Kevin; Mahajani, Varad; Panchal, Reena A.; Sharma, Shyam; Koratkar, Nikhil (July 2022, Proceedings of the National Academy of Sciences)

   Looming concerns regarding scarcity, high prices, and safety threaten the long-term use of lithium in energy storage devices. Calcium has been explored in batteries because of its abundance and low cost, but the larger size and higher charge density of calcium ions relative to lithium impairs diffusion kinetics and cyclic stability. In this work, an aqueous calcium–ion battery is demonstrated using orthorhombic, trigonal, and tetragonal polymorphs of molybdenum vanadium oxide (MoVO) as a host for calcium ions. Orthorhombic and trigonal MoVOs outperform the tetragonal structure because large hexagonal and heptagonal tunnels are ubiquitous in such crystals, providing facile pathways for calcium–ion diffusion. For trigonal MoVO, a specific capacity of ∼203 mAh g −1 was obtained at 0.2C and at a 100 times faster rate of 20C, an ∼60 mAh g −1 capacity was achieved. The open-tunnel trigonal and orthorhombic polymorphs also promoted cyclic stability and reversibility. A review of the literature indicates that MoVO provides one of the best performances reported to date for the storage of calcium ions. 

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5. Metallic FeSe monolayer as an anode material for Li and non-Li ion batteries: a DFT study

   https://doi.org/10.1039/D0CP00967A  

   Lv, Xiaodong; Li, Fengyu; Gong, Jian; Gu, Jinxing; Lin, Shiru; Chen, Zhongfang (April 2020, Physical Chemistry Chemical Physics)

   By means of density functional theory computations, we explored the electrochemical performance of an FeSe monolayer as an anode material for lithium and non-lithium ion batteries (LIBs and NLIBs). The electronic structure, adsorption, diffusion, and storage behavior of different metal atoms (M) in FeSe were systematically investigated. Our computations revealed that M adsorbed FeSe (M = Li, Na and K) systems show metallic characteristics that give rise to good electrical conductivity and mobility with low activation energies for diffusion (0.16, 0.13 and 0.11 eV for Li, Na, and K, respectively) of electrons and metal atoms in the materials, indicative of a fast charge/discharge rate. In addition, the theoretical capacities of the FeSe monolayer for Li, Na and K can reach up to 658, 473, and 315 mA h g −1 , respectively, higher than that of commercial graphite (372 mA h g −1 for Li, 284 mA h g −1 for Na, and 273 mA h g −1 for K), and the average open-circuit voltage is moderate (0.38–0.88 V for Li, Na and K). All these characteristics suggest that the FeSe monolayer is a potential anode material for alkali-metal rechargeable batteries. 

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