Heterogeneity of Graphite Lithiation in State‐of‐the‐Art Cylinder‐Type Li‐Ion Cells

Petz, Dominik; Mühlbauer, Martin; Schökel, Alexander; Achterhold, Klaus; Pfeiffer, Franz; Pirling, Thilo; Hofmann, M.; Senyshyn, Anatoliy

doi:10.1002/batt.202000178

Cited by 10 publications

(15 citation statements)

References 50 publications

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“…As described above, the c/a-ratio is correlated with the local SOC, see Figure 2. However, the state of lithiation in the cathode is less sensitive to the current distribution when compared to the graphite anode (25). The area of uniformly lithiated cathode exceeds that of the anode, and the edges with nonuniform lithiation are significantly narrower than those in the graphite anode.…”

Section: Spatially Resolved Powder X-ray Diffractionmentioning

confidence: 96%

Methods—Spatially Resolved Diffraction Study of the Uniformity of a Li-Ion Pouch Cell

Sørensen

Heere

Smith

et al. 2022

J. Electrochem. Soc.

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A lab-made, multilayered Li-ion battery pouch cell is investigated using in-operando neutron powder diffraction (NPD) and spatially resolved powder X-ray diffraction (SR-PXRD) with the aim of investigating how to compare the information obtained from the two complementary techniques on a cell type with a complicated geometry for diffraction. The work focusses on the anode and cathode lithiation as obtained from the LiC6/LiC12 weight ratio and the NMC111 c/a-ratio, respectively. Neutron powder diffractograms of a sufficient quality for Rietveld refinement are measured using a rotation stage to minimize geometrical effects. Using SR-PXRD, the cell is shown to be non-uniform in its anode and cathode lithiation, with the edges of the cell being less lithiated/delithiated than the center in the fully charged state. The non-uniformity is more pronounced for high charging current than low charging current. The averaged SR-PXRD data is found to match the bulk NPD data well. This is encouraging as it seems to allow comparisons between studies using either of these complementary techniques. This work will also serve as a benchmark for our future studies on pouch cells with novel non-commercial cathode and/or anode materials.

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Section: Spatially Resolved Powder X-ray Diffractionmentioning

confidence: 96%

Methods—Spatially Resolved Diffraction Study of the Uniformity of a Li-Ion Pouch Cell

Sørensen

Heere

Smith

et al. 2022

J. Electrochem. Soc.

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“…[32] On the other hand, the temperature distribution at the extremum point (transition 1-2, at the vicinity of SOC 100 state), recently reported for a series of pouch bag cells [33] have been found very similar to the lithium distribution in the graphite anode [34,35] determined using X-ray diffraction radiography. Degree and uniformity of such lithium distribution has been found seriously affected by cell aging, [27,36,37] which can also take place for temperature surface profile.…”

Section: Average Aging Behaviormentioning

confidence: 99%

“…Application of the distribution histogram analysis (similar to this reported in refs. [34,35,37]) enabled an unambiguous estimate of relevant distribution parameters. For example, the position of the peak in the histograms corresponds to the plateau concentration, and its width indicates the distribution quality while the fraction of the peak area over the total histogram area points on the degree of homogeneity.…”

Section: Spatial In-plane Distribution Of Lithium and Electrolyte Ver...mentioning

confidence: 99%

Aging‐Driven Composition and Distribution Changes of Electrolyte and Graphite Anode in 18650‐Type Li‐Ion Batteries

Petz

Baran

Peschel

et al. 2022

Advanced Energy Materials

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A series of low‐temperature studies on LiNi0.80Co0.15Al0.05O2 18650‐type batteries of high‐energy type with different stabilized states of fatigue is carried out using spatially resolved neutron powder diffraction, infrared/thermal imaging, and quasi‐adiabatic calorimetry. In‐plane distribution of lithium in the graphite anode and frozen electrolyte in fully charged state is determined non‐destructively with neutron diffraction and correlated to the introduced state of fatigue. An independent electrolyte characterization is performed via calorimetry studies on variously aged 18650‐type lithium‐ion batteries, where the shape of the thermodynamic signal is evolving with the state of fatigue of the cells. Analyzing the liquid electrolyte extracted/harvested from the studied cells reveals the decomposition of conducting salt to be the main driving factor for fatigue in the electrolyte degradation.

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“…Spatially resolved operando diffraction experiments are crucial to studying structural evolutions such as homogeneity and phase distribution in battery electrodes during operation,for example, phase redistribution in zinc–air batteries, [ 62 ] lithiation heterogeneities in graphite, [ 25 ] and silicon‐graphite, [ 63 ] long‐term cycling stability of high voltage spinel cathode versus graphite, [ 48,64 ] degradation mechanisms in Li–S batteries up to 35 cycles, [ 65 ] or NPD mappings. [ 66,67 ] Computed tomography (CT) methods are able to describe the macrostructure, interconnectivity, and electronic percolation in the electrodes with a spatial resolution from <100 nm to several micrometers. [ 68 ] The contrast in CT is obtained through absorption, phase shift or scattering methods, giving access to the crystal/nano structure (XRD‐CT, SAXS‐CT), oxidation state, and lithium‐ion bulk migration (NI, NCT), depending on the experimental methods employed.…”

Section: Neutron and Synchrotron Bulk Characterization Techniquesmentioning

confidence: 99%

“…[68] The contrast in CT is obtained through absorption, phase shift or scattering methods, giving access to the crystal/nano structure (XRD-CT, SAXS-CT), oxidation state, and lithium-ion bulk migration (NI, NCT), depending on the experimental methods employed. [66,69] μCT and nanoCT techniques provide invaluable insights into the mechanical and morphological degradation of electrodes, both of which play key roles in the performance decay for in state-of-the art lithium ion batteries as well as next generation technologies, for example, allsolid-state, [70,71] M-ion, [28,72] Li-O 2 [73,74] and Li-S batteries. [75] For instance, Na electrodeposits were observed in solid state batteries by μCT and found to increase interfacial resistance and hinder ion diffusion, resulting in performance decay.…”

Section: Spatially-resolved Techniquesmentioning

confidence: 99%

Accelerating Battery Characterization Using Neutron and Synchrotron Techniques: Toward a Multi‐Modal and Multi‐Scale Standardized Experimental Workflow

Atkins

Capria

Edström

et al. 2021

Advanced Energy Materials

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Li‐ion batteries are the essential energy‐storage building blocks of modern society. However, producing ultra‐high electrochemical performance in safe and sustainable batteries for example, e‐mobility, and portable and stationary applications, demands overcoming major technological challenges. Materials engineering and new chemistries are key aspects to achieving this objective, intimately linked to the use of advanced characterization techniques. In particular, operando investigations are currently attracting enormous interest. Synchrotron‐ and neutron‐based bulk techniques are increasingly employed as they provide unique insights into the chemical, morphological, and structural changes inside electrodes and electrolytes across multiple length scales with high time/spatial resolutions. However, data acquisition, data analysis, and scientific outcomes must be accelerated to increase the overall benefits to the academic and industrial communities, requiring a paradigm shift beyond traditional single‐shot, sophisticated experiments. Here a multi‐scale and multi‐technique integrated workflow is presented to enhance bulk characterization, based on standardized and automated data acquisition and analysis for high‐throughput and high‐fidelity experiments, the optimization of versatile and tunable cells, as well as multi‐modal correlative characterization. Furthermore, new mechanisms, methods and organizations such as artificial intelligence‐aided modeling‐driven strategies, coordinated beamtime allocations, and community‐unified infrastructures are discussed in order to highlight perspectives in battery research at large scale facilities.

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Heterogeneity of Graphite Lithiation in State‐of‐the‐Art Cylinder‐Type Li‐Ion Cells

Cited by 10 publications

References 50 publications

Methods—Spatially Resolved Diffraction Study of the Uniformity of a Li-Ion Pouch Cell

Methods—Spatially Resolved Diffraction Study of the Uniformity of a Li-Ion Pouch Cell

Aging‐Driven Composition and Distribution Changes of Electrolyte and Graphite Anode in 18650‐Type Li‐Ion Batteries

Accelerating Battery Characterization Using Neutron and Synchrotron Techniques: Toward a Multi‐Modal and Multi‐Scale Standardized Experimental Workflow

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