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1. An Atomic View of Cation Diffusion Pathways from Single‐Crystal Topochemical Transformations

   https://doi.org/10.1002/anie.202005513  

   Handy, Joseph V. ; Luo, Yuting ; Andrews, Justin L. ; Bhuvanesh, Nattamai ; Banerjee, Sarbajit ( July 2020 , Angewandte Chemie International Edition)

   The diffusion pathways of Li‐ions as they traverse cathode structures in the course of insertion reactions underpin many questions fundamental to the functionality of Li‐ion batteries. Much current knowledge derives from computational models or the imaging of lithiation behavior at larger length scales; however, it remains difficult to experimentally image Li‐ion diffusion at the atomistic level. Here, by using topochemical Li‐ion insertion and extraction to induce single‐crystal‐to‐single‐crystal transformations in a tunnel‐structured V₂O₅polymorph, coupled with operando powder X‐ray diffraction, we leverage single‐crystal X‐ray diffraction to identify the sequence of lattice interstitial sites preferred by Li‐ions to high depths of discharge, and use electron density maps to create a snapshot of ion diffusion in a metastable phase. Our methods enable the atomistic imaging of Li‐ions in this cathode material in kinetic states and provide an experimentally validated angstrom‐level 3D picture of atomic pathways thus far only conjectured through DFT calculations.

    

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2. Cation reordering instead of phase transitions: Origins and implications of contrasting lithiation mechanisms in 1D ζ- and 2D α-V 2 O 5

   https://doi.org/10.1073/pnas.2115072119  

   Luo, Yuting ; Rezaei, Shahed ; Santos, David A. ; Zhang, Yuwei ; Handy, Joseph V. ; Carrillo, Luis ; Schultz, Brian J. ; Gobbato, Leonardo ; Pupucevski, Max ; Wiaderek, Kamila ; et al ( January 2022 , Proceedings of the National Academy of Sciences)

   Substantial improvements in cycle life, rate performance, accessible voltage, and reversible capacity are required to realize the promise of Li-ion batteries in full measure. Here, we have examined insertion electrodes of the same composition (V 2 O 5 ) prepared according to the same electrode specifications and comprising particles with similar dimensions and geometries that differ only in terms of their atomic connectivity and crystal structure, specifically two-dimensional (2D) layered α-V 2 O 5 that crystallizes in an orthorhombic space group and one-dimensional (1D) tunnel-structured ζ-V 2 O 5 crystallized in a monoclinic space group. By using particles of similar dimensions, we have disentangled the role of specific structural motifs and atomistic diffusion pathways in affecting electrochemical performance by mapping the dynamical evolution of lithiation-induced structural modifications using ex situ scanning transmission X-ray microscopy, operando synchrotron X-ray diffraction measurements, and phase-field modeling. We find the operation of sharply divergent mechanisms to accommodate increasing concentrations of Li-ions: a series of distortive phase transformations that result in puckering and expansion of interlayer spacing in layered α-V 2 O 5 , as compared with cation reordering along interstitial sites in tunnel-structured ζ-V 2 O 5 . By alleviating distortive phase transformations, the ζ-V 2 O 5 cathode shows reduced voltage hysteresis, increased Li-ion diffusivity, alleviation of stress gradients, and improved capacity retention. The findings demonstrate that alternative lithiation mechanisms can be accessed in metastable compounds by dint of their reconfigured atomic connectivity and can unlock substantially improved electrochemical performance not accessible in the thermodynamically stable phase. 

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3. [LiCl 2 ] − Superhalide: A New Charge Carrier for Graphite Cathode of Dual‐Ion Batteries

   https://doi.org/10.1002/adfm.202112709  

   Kim, Keun‐il ; Tang, Longteng ; Mirabedini, Pegah ; Yokoi, Amika ; Muratli, Jesse M. ; Guo, Qiubo ; Lerner, Michael M. ; Gotoh, Kazuma ; Greaney, Peter Alex ; Fang, Chong ; et al ( March 2022 , Advanced Functional Materials)

   New acceptor‐type graphite intercalation compounds (GICs) offer candidates of cathode materials for dual‐ion batteries (DIBs), where superhalides represent the emerging anion charge carriers for such batteries. Here, the reversible insertion of [LiCl₂]⁻into graphite from an aqueous deep eutectic solvent electrolyte of 20mLiCl+20mcholine chloride is reported. [LiCl₂]⁻is the primary anion species in this electrolyte as revealed by the femtosecond stimulated Raman spectroscopy results, particularly through the rarely observed H–O–H bending mode. The insertion of Li–Cl anionic species is suggested by⁷Li magic angle spinning nuclear magnetic resonance results that describe a unique chemical environment of Li⁺ions with electron donors around.²H nuclear magnetic resonance results suggest that water molecules are co‐inserted into graphite. Density functional theory calculations reveal that the anionic insertion of hydrated [LiCl₂]⁻takes place at a lower potential, being more favorable. X‐ray diffraction and the Raman results show that the insertion of [LiCl₂]⁻creates turbostratic structure in graphite instead of forming long‐range ordered GICs. The storage of [LiCl₂]⁻in graphite as a cathode for DIBs offers a capacity of 114 mAh g⁻¹that is stable over 440 cycles.

    

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4. Reactivity with Water and Bulk Ruthenium Redox of Lithium Ruthenate in Basic Solutions

   https://doi.org/10.1002/adfm.202002249  

   Rao, Reshma R. ; Tułodziecki, Michał ; Han, Binghong ; Risch, Marcel ; Abakumov, Artem ; Yu, Yang ; Karayaylali, Pinar ; Gauthier, Magali ; Escudero‐Escribano, María ; Orikasa, Yuki ; et al ( July 2020 , Advanced Functional Materials)

   The reactivity of water with Li‐rich layered Li₂RuO₃and partial exchange of Li₂O with H₂O within the structure is studied under aqueous (electro)chemical conditions. Upon slow delithiation in water over long time periods, micron‐sized Li₂RuO₃particles structurally transform from an O3 structure to an O1 structure with a corresponding loss of 1.25 Li ions per formula unit. The O1 stacking of the honeycomb Ru layers is imaged using high‐resolution high‐angle annular dark‐field scanning transmission electron microscopy, and the resulting structure is solved by X‐ray powder diffraction and electron diffraction. In situ X‐ray absorption spectroscopy suggests that reversible oxidation/reduction of bulk Ru sites is realized on potential cycling between 0.4 and 1.25 V_RHEin basic solutions. In addition to surface redox pseudocapacitance, the partially delithiated phase of Li₂RuO₃shows high capacity, which can be attributed to bulk Ru redox in the structure. This work demonstrates that the interaction of aqueous electrolytes with Li‐rich layered oxides can result in the formation of new phases with (electro)chemical properties that are distinct from the parent material. This understanding is important for the design of aqueous batteries, electrochemical capacitors, and chemically stable cathode materials for Li‐ion batteries.

    

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5. Computational Modeling of Heterogeneity of Stress, Charge, and Cyclic Damage in Composite Electrodes of Li-Ion Batteries

   https://doi.org/10.1149/1945-7111/ab78fa  

   Liu, Pengfei ; Xu, Rong ; Liu, Yijin ; Lin, Feng ; Zhao, Kejie ( March 2020 , Journal of The Electrochemical Society)

   Charge heterogeneity is a prevalent feature in many electrochemical systems. In a commercial cathode of Li-ion batteries, the composite is hierarchically structured across multiple length scales including the sub-micron single-crystal primary-particle domains up to the macroscopic particle ensembles. The redox kinetics of charge transfer and mass transport strongly couples with mechanical stresses. This interplay catalyzes substantial heterogeneity in the charge (re)distribution, stresses, and mechanical damage in the composite electrode during charging and discharging. We assess the heterogeneous electrochemistry and mechanics in a LiNi_xMn_yCo_zO₂(NMC) cathode using a fully coupled electro-chemo-mechanics model at the cell level. A microstructure-resolved model is constructed based on the synchrotron X-ray tomography data. We calculate the stress field in the composite and then quantitatively evaluate the kinetics of surface charge transfer and Li transport biased by mechanical stresses. We further model the cyclic behavior of the cell. The repetitive deformation of the active particles and the weakening of the interfacial strength cause gradual increase of the interfacial debonding. The mechanical damage impedes electron transfer, incurs more charge heterogeneity, and results in the capacity degradation in batteries over cycles.

    

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