Your search keyword '"Fiona C. Strobridge"' showing total 5 results

1. Nanoscale Detection of Intermediate Solid Solutions in Equilibrated LixFePO4 Microcrystals

Author

Clare P. Grey, Jordi Cabana, Martin V. Holt, Fiona C. Strobridge, Ulrike Boesenberg, Brian M. May, and Young-Sang Yu

Subjects

Diffraction, Materials science, Mechanical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Miscibility, 0104 chemical sciences, Chemical physics, Phase (matter), Metastability, Particle, General Materials Science, 0210 nano-technology, Nanoscopic scale, Phase diagram, Solid solution

Abstract

Redox-driven phase transformations in solids determine the performance of lithium-ion batteries, crucial in the technological transition from fossil fuels. Couplings between chemistry and strain define reversibility and fatigue of an electrode. The accurate definition of all phases in the transformation, their energetics, and nanoscale location within a particle produces fundamental understanding of these couplings needed to design materials with ultimate performance. Here we demonstrate that scanning X-ray diffraction microscopy (SXDM) extends our ability to image battery processes in single particles. In LiFePO4 crystals equilibrated after delithiation, SXDM revealed the existence of domains of miscibility between LiFePO4 and Li0.6FePO4. These solid solutions are conventionally thought to be metastable, and were previously undetected by spectromicroscopy. The observation provides experimental verification of predictions that the LiFePO4–FePO4 phase diagram can be altered by coherency strain under certai...

Published

2017

2. Localized concentration reversal of lithium during intercalation into nanoparticles

Author

Aziz Abdellahi, Yimei Zhu, Wei Zhang, Xufeng Zhou, Bernardo Orvananos, Feng Wang, Clare P. Grey, Lijun Wu, Bao Qiu, Gerbrand Ceder, Fiona C. Strobridge, Katsuyo Thornton, Zhaoping Liu, Jianming Bai, Hao Liu, Hui-Chia Yu, Zhang, Wei [0000-0001-7031-162X], Yu, Hui-Chia [0000-0002-4351-3581], Wu, Lijun [0000-0002-8443-250X], Liu, Hao [0000-0003-0345-6647], Abdellahi, Aziz [0000-0001-8046-4996], Qiu, Bao [0000-0002-7505-6135], Bai, Jianming [0000-0002-0575-2987], Zhou, Xufeng [0000-0002-3153-6954], Zhu, Yimei [0000-0002-1638-7217], Thornton, Katsuyo [0000-0002-1227-5293], Grey, Clare P [0000-0001-5572-192X], Wang, Feng [0000-0003-4068-9212], and Apollo - University of Cambridge Repository

Subjects

Materials science, Intercalation (chemistry), Nanoparticle, Non-equilibrium thermodynamics, Bioengineering, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, 4016 Materials Engineering, Lattice constant, Nanotechnology, Research Articles, 40 Engineering, Power density, FOS: Nanotechnology, Multidisciplinary, 34 Chemical Sciences, SciAdv r-articles, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Applied Sciences and Engineering, Chemical physics, Electrode, 3406 Physical Chemistry, Nanometre, 0210 nano-technology, Research Article

Abstract

Inhomogeneous Li intercalation and localized concentration reversal in nanoparticles are investigated on a nanometer scale., Nanoparticulate electrodes, such as LixFePO4, have unique advantages over their microparticulate counterparts for the applications in Li-ion batteries because of the shortened diffusion path and access to nonequilibrium routes for fast Li incorporation, thus radically boosting power density of the electrodes. However, how Li intercalation occurs locally in a single nanoparticle of such materials remains unresolved because real-time observation at such a fine scale is still lacking. We report visualization of local Li intercalation via solid-solution transformation in individual LixFePO4 nanoparticles, enabled by probing sub-angstrom changes in the lattice spacing in situ. The real-time observation reveals inhomogeneous intercalation, accompanied with an unexpected reversal of Li concentration at the nanometer scale. The origin of the reversal phenomenon is elucidated through phase-field simulations, and it is attributed to the presence of structurally different regions that have distinct chemical potential functions. The findings from this study provide a new perspective on the local intercalation dynamics in battery electrodes.

Published

2017

3. Density Functional Theory-Based Bond Pathway Decompositions of Hyperfine Shifts: Equipping Solid-State NMR to Characterize Atomic Environments in Paramagnetic Materials

Author

Andrew J. Ilott, Fiona C. Strobridge, Raphaële J. Clément, Derek S. Middlemiss, and Clare P. Grey

Subjects

Fermi contact interaction, Condensed matter physics, Chemistry, General Chemical Engineering, Jahn–Teller effect, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, NMR spectra database, Paramagnetism, Solid-state nuclear magnetic resonance, Chemical physics, Materials Chemistry, Condensed Matter::Strongly Correlated Electrons, Density functional theory, 0210 nano-technology, Spin (physics), Hyperfine structure

Abstract

Solid-state nuclear magnetic resonance (NMR) of paramagnetic samples has the potential to provide a detailed insight into the environments and processes occurring in a wide range of technologically-relevant phases, but the acquisition and interpretation of spectra is typically not straightforward. Structural complexity and/or the occurrence of charge or orbital ordering further compound such difficulties. In response to such challenges, the present article outlines how the total Fermi contact (FC) shifts of NMR observed centers (OCs) may be decomposed into sets of pairwise metal–OC bond pathway contributions via solid-state hybrid density functional theory calculations. A generally applicable “spin flipping” approach is outlined wherein bond pathway contributions are obtained by the reversal of spin moments at selected metal sites. The applications of such pathway contributions in interpreting the NMR spectra of structurally and electronically complex phases are demonstrated in a range of paramagnetic Li-...

Published

2013

4. Three dimensional localization of nanoscale battery reactions using soft X-ray tomography

Author

Stefano Marchesini, John Joseph, Filipe R. N. C. Maia, Howard A. Padmore, Richard Celestre, Talita Perciano Costa Leite, Peter Denes, Young-Sang Yu, David A. Shapiro, Fiona C. Strobridge, A. L. David Kilcoyne, Clare P. Grey, Harinarayan Krishnan, Jordi Cabana, Maryam Farmand, Tony Warwick, Chunjoong Kim, Yijin Liu, Tolek Tyliszczak, Liu, Yijin [0000-0002-8417-2488], Celestre, Rich [0000-0003-1897-851X], Krishnan, Harinarayan [0000-0001-8018-0547], Kilcoyne, AL David [0000-0002-8805-8690], Leite, Talita Perciano Costa [0000-0002-2388-1803], Cabana, Jordi [0000-0002-2353-5986], Shapiro, David A [0000-0002-4186-6017], and Apollo - University of Cambridge Repository

Subjects

Battery (electricity), Materials science, Science, Materialkemi, General Physics and Astronomy, FOS: Physical sciences, Nanotechnology, Bioengineering, 02 engineering and technology, Applied Physics (physics.app-ph), 010402 general chemistry, Physical Chemistry, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, chemistry.chemical_compound, Affordable and Clean Energy, Phase (matter), Materials Chemistry, lcsh:Science, Image resolution, Fysikalisk kemi, Condensed Matter - Materials Science, Multidisciplinary, Lithium iron phosphate, Materials Science (cond-mat.mtrl-sci), Physics - Applied Physics, General Chemistry, 021001 nanoscience & nanotechnology, cond-mat.mtrl-sci, 0104 chemical sciences, Chemical state, State of charge, chemistry, Electrode, lcsh:Q, Tomography, 0210 nano-technology, physics.app-ph

Abstract

Battery function is determined by the efficiency and reversibility of the electrochemical phase transformations at solid electrodes. The microscopic tools available to study the chemical states of matter with the required spatial resolution and chemical specificity are intrinsically limited when studying complex architectures by their reliance on two-dimensional projections of thick material. Here, we report the development of soft X-ray ptychographic tomography, which resolves chemical states in three dimensions at 11 nm spatial resolution. We study an ensemble of nano-plates of lithium iron phosphate extracted from a battery electrode at 50% state of charge. Using a set of nanoscale tomograms, we quantify the electrochemical state and resolve phase boundaries throughout the volume of individual nanoparticles. These observations reveal multiple reaction points, intra-particle heterogeneity, and size effects that highlight the importance of multi-dimensional analytical tools in providing novel insight to the design of the next generation of high-performance devices., Here the authors show the development of soft X-ray ptychographic tomography to quantify the electrochemical state and resolve phase boundaries throughout the volume of individual nano-particles from a composite battery electrode.

Published

2017

5. Spin-Transfer Pathways in Paramagnetic Lithium Transition-Metal Phosphates from Combined Broadband Isotropic Solid-State MAS NMR Spectroscopy and DFT Calculations

Author

Derek S. Middlemiss, Andrew J. Pell, Lyndon Emsley, Fiona C. Strobridge, Raphaële J. Clément, Clare P. Grey, Guido Pintacuda, Joel K. Miller, M. Stanley Whittingham, ISA - Centre de RMN à très hauts champs, Institut des Sciences Analytiques (ISA), Institut de Chimie du CNRS (INC)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), Dept Chemistry, University of Cambridge [UK] (CAM), SUNY Binghamton, ANR (ANR-08-BLAN-0035: PARA-NMR), U.S. Department of Energy, Office of Basic Energy Sciences (DE-AC02-98CH10886), EPSRC (EP/F067496), Office of Science and Technology through the EPSRC's High End Computing Programme, NECCES (DOE Energy Frontier Research Center) DE-SC0001294, and EPSRC

Subjects

Magnetic Resonance Spectroscopy, Analytical chemistry, chemistry.chemical_element, 02 engineering and technology, Electronic structure, Lithium, 010402 general chemistry, 7. Clean energy, 01 natural sciences, Biochemistry, Catalysis, Lithium-ion battery, HYDROTHERMAL SYNTHESIS, Phosphates, SENSITIVITY ENHANCEMENT, Paramagnetism, Colloid and Surface Chemistry, QUADRUPOLAR NUCLEI, [CHIM.ANAL]Chemical Sciences/Analytical chemistry, Transition Elements, SPECTRA, SIDE-BAND, ION BATTERIES, Hyperfine structure, ADIABATIC PULSES, Chemistry, Chemical shift, Phosphorus Isotopes, General Chemistry, 021001 nanoscience & nanotechnology, CATHODE MATERIALS, 0104 chemical sciences, Characterization (materials science), NMR spectra database, RECHARGEABLE BATTERIES, RESOLUTION, Chemical physics, Quantum Theory, 0210 nano-technology

Abstract

International audience; Substituted lithium transition-metal (TM) phosphate LiFexMn1-xPO4, materials with olivine-type structures are among the most promising next generation lithium ion battery cathodes. However, a complete atomic-level description of the structure of such phases is not yet available. Here, a combined experimental and theoretical approach to the detailed assignment of the P-31 NMR spectra of the LiFexMn1-xPO4 (x = 0, 0.25, 0.5, 0.75, 1) pure and mixed TM phosphates is developed and applied. Key to the present work is the development of a new NMR experiment enabling the characterization of complex paramagnetic materials via the complete separation of the individual isotropic chemical shifts, along with solid-state hybrid DFT calculations providing the separate hyperfine contributions of all distinct Mn-O-P and Fe-O-P bond pathways. The NMR experiment, referred to as aMAT, makes use of short high-powered adiabatic pulses (SHAPs), which can achieve 100% inversion over a range of isotropic shifts on the order of 1 MHz and with anisotropies greater than 100 kHz. In addition to complete spectral assignments of the mixed phases, the present study provides a detailed insight into the differences in electronic structure driving the variations in hyperfine parameters across the range of materials. A simple model delimiting the effects of distortions due to Mn/Fe substitution is also proposed and applied. The combined approach has clear future applications to TM-bearing battery cathode phases in particular and for the understanding of complex paramagnetic phases in general.

Published

2012