Exploring Cation-Anion Redox Processes in One-Dimensional Linear Chain Vanadium Tetrasulfide Rechargeable Magnesium Ion Cathodes.

For magnesium ion batteries (MIBs) to be used commercially, new cathodes must be developed that show stable reversible Mg intercalation. VS4 is one such promising material, with vanadium and disulfide anions [S2]2- forming one-dimensional linear chains, with a large interchain spacing (5.83 Å) enabling reversible Mg insertion. However, little is known about the details of the redox processes and structural transformations that occur upon Mg intercalation and deintercalation. Here, employing a suite of local structure characterization methods including X-ray photoelectron spectroscopy (XPS), V and S X-ray absorption near-edge spectroscopy (XANES), and 51V Hahn echo and magic-angle turning with phase-adjusted sideband separation (MATPASS) NMR, we show that the reaction proceeds via internal electron transfer from V4+ to [S2]2-, resulting in the simultaneous and coupled oxidation of V4+ to V5+ and reduction of [S2]2- to S2-. We report the formation of a previously unknown intermediate in the Mg-V-S compositional space, Mg3V2S8, comprising [VS4]3- tetrahedral units, identified by using density functional theory coupled with an evolutionary structure-predicting algorithm. The structure is verified experimentally via X-ray pair distribution function analysis. The voltage associated with the competing conversion reaction to form MgS plus V metal directly is similar to that of intermediate formation, resulting in two competing reaction pathways. Partial reversibility is seen to re-form the V5+ and S2- containing intermediate on charging instead of VS4. This work showcases the possibility of developing a family of transition metal polychalcogenides functioning via coupled cationic-anionic redox processes as a potential way of achieving higher capacities for MIBs.S. D. acknowledges DST Overseas Visiting Fellowship in Nano Science and Technology, Government of India (July 2018− June 2019) and EPSRC Programme Grant (EP/M009521/1) for fellowships and funding. This work used the ARCHER UK National Super-computing Service (http://www.archer.ac.uk). This research used resources of the Center for Functional Nanomaterials, which is a U.S. DOE Office of Science Facility, and the Scientific Data and Computing Center, a component of the Computational Science Initiative, at Brookhaven National Laboratory under Contract No. DE-SC0012704. The XPS data collection was performed at the EPSRC National Facility for XPS ("HarwellXPS"), operated by Cardiff University and UCL, under Contract No. PR16195. via our membership of the UK's HEC Materials Chemistry Consortium, which is funded by EPSRC (EP/L000202)

Exploring the Role of Cluster Formation in UiO Family Hf Metal-Organic Frameworks with in Situ X-ray Pair Distribution Function Analysis

The structures of Zr and Hf metal-organic frameworks (MOFs) are very sensitive to small changes in synthetic conditions. One key difference affecting the structure of UiO MOF phases is the shape and nuclearity of Zr or Hf metal clusters acting as nodes in the framework; although these clusters are crucial, their evolution during MOF synthesis is not fully understood. In this paper, we explore the nature of Hf metal clusters that form in different reaction solutions, including in a mixture of DMF, formic acid, and water. We show that the choice of solvent and reaction temperature in UiO MOF syntheses determines the cluster identity and hence the MOF structure. Using in situ X-ray pair distribution function measurements, we demonstrate that the evolution of different Hf cluster species can be tracked during UiO MOF synthesis, from solution stages to the full crystalline framework, and use our understanding to propose a formation mechanism for the hcp UiO-66(Hf) MOF, in which first the metal clusters aggregate from the M6 cluster (as in fcu UiO-66) to the hcp-characteristic M12 double cluster and, following this, the crystalline hcp framework forms. These insights pave the way toward rationally designing syntheses of as-yet unknown MOF structures, via tuning the synthesis conditions to select different cluster species

Exploring the Peierls-Distorted Vanadium Sulphide as A Rechargeable Mg-Ion Cathod .pdf

For magnesium ion batteries (MIB) to be used commercially, new cathodes must be developed that show stable reversible Mg intercalation. VS4 is one such promising material, with vanadium and disulphide anions [S2]2- forming one dimensional linear chains, with a large interlayer spacing (5.83 Å) enabling Mg insertion. However, little is known about the details of the redox processes and structural transformations that occur upon Mg intercalation and deintercalation of VS4. Here we use a suite of local structure characterization methods including XPS, V and S X-ray Absorption Near Edge Spectroscopy and 51V Hahn-Echo and Magic Angle Turning with Phase Adjusted Sideband Separation NMR to elucidate the complex electrochemical reaction pathways. We show that the reaction proceeds via internal electron transfer from V4+ to [S2]2, resulting in the simultaneous and coupled oxidation of V4+ to V5+ and reduction of [S2]2- to S2-. We report the formation of a previously unknown intermediate in the Mg-V-S compositional space, Mg3V2S8, which is made of [VS4]3- tetrahedral units and identified using an evolutionary structure predicting algorithm and verified experimentally via X-ray Pair Distribution Function analysis. Subsequent magnesiation gives rise to the reduction of V5+ towards V4+. Further magnesiation sees conversion to MgS plus V metal; this reaction potential is close to the conversion potential of VS4 to Mg3V2S8, leading to competing reaction pathways. Demagnesiation results in the reformation of the V5+, S2- containing intermediate instead of VS4. This work showcases the possibility of developing a family of transition metal polychalcogenides functioning via anionic as well as combined cationic-anionic redox processes, as a potential way of achieving higher capacities for MIBs.</p

Correlating Local Structure and Sodium Storage in Hard Carbon Anodes: Insights from Pair Distribution Function Analysis and Solid-State NMR.

Hard carbons are the leading candidate anode materials for sodium-ion batteries. However, the sodium-insertion mechanisms remain under debate. Here, employing a novel analysis of operando and ex situ pair distribution function (PDF) analysis of total scattering data, supplemented by information on the local electronic structure provided by operando 23Na solid-state NMR, we identify the local atomic environments of sodium stored within hard carbon and provide a revised mechanism for sodium storage. The local structure of carbons is well-described by bilayers of curved graphene fragments, with fragment size increasing, and curvature decreasing with increasing pyrolysis temperature. A correlation is observed between the higher-voltage (slope) capacity and the defect concentration inferred from the size and curvature of the fragments. Meanwhile, a larger lower-voltage (plateau) capacity is observed in samples modeled by larger fragment sizes. Operando PDF data on two commercially relevant hard carbons reveal changes at higher-voltages consistent with sodium ions stored close to defective areas of the carbon, with electrons localized in the antibonding π*-orbitals of the carbon. Metallic sodium clusters approximately 13-15 Å in diameter are formed in both carbons at lower voltages, implying that, for these carbons, the lower-voltage capacity is determined by the number of regions suitable for sodium cluster formation, rather than by having microstructures that allow larger clusters to form. Our results reveal that local atomic structure has a definitive role in determining storage capacity, and therefore the effect of synthetic conditions on both the local atomic structure and the microstructure should be considered when engineering hard carbons.ACKNOWLEDGMENTS We acknowledge Diamond Light Source for time on I15 and I15-1 under proposals EE17785-1 and EE13681-1. J.M.S was supported by the US DoE under Prime Contract no. DE-AC02-05CH11231 (Sub-contract no. 7368738 via Lawrence Berkeley National La-boratory). C.P.G acknowledges support from the Faraday Institu-tion (grant FIRG018). P.K.A acknowledges a Birmingham Fellow-ship from the University of Birmingham. M.T would like to acknowledge EPSRC grants EP/R021554/2 and EP/S018204/2. S.S.M, J.B and C.W.R acknowledge Dr Steven Huband from the University of Warwick for SAXS data acquisition and modelling