Your search keyword '"Orvananos B"' showing total 3 results

1. Mapping the inhomogeneous electrochemical reaction through porous LiFePO4-electrodes in a standard coin cell battery

Author

Strobridge, FC, Orvananos, B, Croft, M, Yu, HC, Robert, R, Liu, H, Zhong, Z, Connolley, T, Drakopoulos, M, Thornton, K, Grey, CP, Grey, Clare [0000-0001-5572-192X], and Apollo - University of Cambridge Repository

Subjects

34 Chemical Sciences, 3406 Physical Chemistry, 7 Affordable and Clean Energy, 4016 Materials Engineering, 40 Engineering

Abstract

[Image - see article] Nanosized, carbon-coated LiFePO4 (LFP) is a promising cathode for Li-ion batteries. However, nano-particles are problematic for electrode design, optimized electrodes requiring high tap densities, good electronic wiring, and a low tortuosity for efficient Li diffusion in the electrolyte in between the solid particles, conditions that are difficult to achieve simultaneously. Using in situ energy-dispersive X-ray diffraction, we map the evolution of the inhomogeneous electrochemical reaction in LFP-electrodes. On the first cycle, the dynamics are limited by Li diffusion in the electrolyte at a cycle rate of C/7. On the second cycle, there appear to be two rate-limiting processes: Li diffusion in the electrolyte and electronic conductivity through the electrode. Three-dimensional modeling based on porous electrode theory shows that this change in dynamics can be reproduced by reducing the electronic conductivity of the composite electrode by a factor of 8 compared to the first cycle. The poorer electronic wiring could result from the expansion and contraction of the particles upon cycling and/or the formation of a solid-electrolyte interphase layer. A lag was also observed perpendicular to the direction of the current: the LFP particles at the edges of the cathode reacted preferentially to those in the middle, owing to the closer proximity to the electrolyte source. Simulations show that, at low charge rates, the reaction becomes more uniformly distributed across the electrode as the porosity or the width of the particle-size distribution is increased. However, at higher rates, the reaction becomes less uniform and independent of the particle-size distribution.

Published

2015

2. Localized concentration reversal of lithium during intercalation into nanoparticles.

Author

Zhang W, Yu HC, Wu L, Liu H, Abdellahi A, Qiu B, Bai J, Orvananos B, Strobridge FC, Zhou X, Liu Z, Ceder G, Zhu Y, Thornton K, Grey CP, and Wang F

Abstract

Nanoparticulate electrodes, such as Li x FePO 4 , 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 Li x FePO 4 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

2018

3. Synthesis of a mixed-valent tin nitride and considerations of its possible crystal structures.

Author

Caskey CM, Holder A, Shulda S, Christensen ST, Diercks D, Schwartz CP, Biagioni D, Nordlund D, Kukliansky A, Natan A, Prendergast D, Orvananos B, Sun W, Zhang X, Ceder G, Ginley DS, Tumas W, Perkins JD, Stevanovic V, Pylypenko S, Lany S, Richards RM, and Zakutayev A

Subjects

Crystallization, Molecular Structure, Quantum Theory, X-Ray Diffraction, Nitriles chemistry, Tin chemistry

Abstract

Recent advances in theoretical structure prediction methods and high-throughput computational techniques are revolutionizing experimental discovery of the thermodynamically stable inorganic materials. Metastable materials represent a new frontier for these studies, since even simple binary non-ground state compounds of common elements may be awaiting discovery. However, there are significant research challenges related to non-equilibrium thin film synthesis and crystal structure predictions, such as small strained crystals in the experimental samples and energy minimization based theoretical algorithms. Here, we report on experimental synthesis and characterization, as well as theoretical first-principles calculations of a previously unreported mixed-valent binary tin nitride. Thin film experiments indicate that this novel material is N-deficient SnN with tin in the mixed ii/iv valence state and a small low-symmetry unit cell. Theoretical calculations suggest that the most likely crystal structure has the space group 2 (SG2) related to the distorted delafossite (SG166), which is nearly 0.1 eV/atom above the ground state SnN polymorph. This observation is rationalized by the structural similarity of the SnN distorted delafossite to the chemically related Sn3N4 spinel compound, which provides a fresh scientific insight into the reasons for growth of polymorphs of metastable materials. In addition to reporting on the discovery of the simple binary SnN compound, this paper illustrates a possible way of combining a wide range of advanced characterization techniques with the first-principle property calculation methods, to elucidate the most likely crystal structure of the previously unreported metastable materials.

Published

2016