Björn Pfeiffer scite author profile

lithium manganese oxide spinel, tetragonal Li 2 Mn 2 O 4 , EELS, twinning, defects, interface, lithiation Spinel lithium manganese oxide (Li x Mn 2 O 4 ) is used as an active material in battery cathodes. It is a relatively inexpensive and environmentally friendly material, but suffers from capacity fade during use. The capacity losses are generally attributed to the formation of the tetragonal phase (x > 1) due to overpotentials at the surfaces of the micron-sized particles that are used in commercial electrodes. In this study, we investigate the mechanisms of tetragonal phase formation by performing electrochemical lithiation (discharging) in-situ in the transmission electron microscope (TEM) utilizing diffraction and high resolution as well as spectroscopy. We observe a sharp interface between the cubic spinel (x = 1) and the tetragonal phase (x = 2), that moves under lithium diffusion-control. The tetragonal phase forms as a complex nanotwinned microstructure, presumably to relieve the stresses due to expansion during lithiation. We propose 2 that the twinned microstructure stabilizes the tetragonal phase, adding to capacity loss upon deep discharge.

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Three‐Dimensional Microstructural Characterization of Lithium Manganese Oxide with Atom Probe Tomography

Maier

Pfeiffer

Volkert

et al. 2016

Energy Tech

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The microstructure of the active material of Li‐ion batteries has a crucial influence on local ion‐transport processes but is not yet well characterized. Atom probe tomography (APT), a method combining sub‐nanometer spatial resolution with sub‐parts‐per‐thousand chemical resolution is well suited for 3 D microstructural characterization. Herein, the results of the characterization of lithium (nickel)manganese oxides [L(N)MO] with APT are presented. Structural and chemical defects of different dimensions such as the segregation of Na impurities to grain boundaries and the appearance of a Ni‐rich foreign phase are detected. Furthermore, a lamellar microstructure correlated to fluctuations in the local Li content was observed, and its influence on Li transport in the material is discussed. In defect‐free regions, the lattice planes of LMO are reconstructed for the first time, and the high spatial resolution of APT is revealed. Thus, the results demonstrate the potential of APT for the 3 D microstructural characterization of LMO.

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In SituAtom Probe Deintercalation of Lithium-Manganese-Oxide

et al. 2017

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Atom probe tomography is routinely used for the characterization of materials microstructures, usually assuming that the microstructure is unaltered by the analysis. When analyzing ionic conductors, however, gradients in the chemical potential and the electric field penetrating dielectric atom probe specimens can cause significant ionic mobility. Although ionic mobility is undesirable when aiming for materials characterization, it offers a strategy to manipulate materials directly in situ in the atom probe. Here, we present experimental results on the analysis of the ionic conductor lithium-manganese-oxide with different atom probe techniques. We demonstrate that, at a temperature of 30 K, characterization of the materials microstructure is possible without measurable Li mobility. Also, we show that at 298 K the material can be deintercalated, in situ in the atom probe, without changing the manganese-oxide host structure. Combining in situ atom probe deintercalation and subsequent conventional characterization, we demonstrate a new methodological approach to study ionic conductors even in early stages of deintercalation.

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Characterization of Nanoporous Materials with Atom Probe Tomography

et al. 2015

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A method to characterize open-cell nanoporous materials with atom probe tomography (APT) has been developed. For this, open-cell nanoporous gold with pore diameters of around 50 nm was used as a model system, and filled by electron beam-induced deposition (EBID) to obtain a compact material. Two different EBID precursors were successfully tested-dicobalt octacarbonyl [Co2(CO)8] and diiron nonacarbonyl [Fe2(CO)9]. Penetration and filling depth are sufficient for focused ion beam-based APT sample preparation. With this approach, stable APT analysis of the nanoporous material can be performed. Reconstruction reveals the composition of the deposited precursor and the nanoporous material, as well as chemical information of the interfaces between them. Thus, it is shown that, using an appropriate EBID process, local chemical information in three dimensions with sub-nanometer resolution can be obtained from nanoporous materials using APT.

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In-situ Deinterkalation von Lithiummanganoxid mittels Atomsondentomographie

Pfeiffer¹

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Björn Pfeiffer

Tracking the Diffusion-Controlled Lithiation Reaction of LiMn₂O₄ by In Situ TEM

Three‐Dimensional Microstructural Characterization of Lithium Manganese Oxide with Atom Probe Tomography

In SituAtom Probe Deintercalation of Lithium-Manganese-Oxide

Characterization of Nanoporous Materials with Atom Probe Tomography

In-situ Deinterkalation von Lithiummanganoxid mittels Atomsondentomographie

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Björn Pfeiffer

Tracking the Diffusion-Controlled Lithiation Reaction of LiMn2O4 by In Situ TEM

Three‐Dimensional Microstructural Characterization of Lithium Manganese Oxide with Atom Probe Tomography

In SituAtom Probe Deintercalation of Lithium-Manganese-Oxide

Characterization of Nanoporous Materials with Atom Probe Tomography

In-situ Deinterkalation von Lithiummanganoxid mittels Atomsondentomographie

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Product

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Tracking the Diffusion-Controlled Lithiation Reaction of LiMn₂O₄ by In Situ TEM