In Situ Imaging of Electrode Thickness Growth and Electrolyte Depletion in Single-Crystal vs Polycrystalline LiNixMnyCozO<sub>2</sub>/Graphite Pouch Cells using Multi-Scale Computed Tomography

Bond, Toby; Gauthier, Roby; Eldesoky, Ahmed; Harlow, Jessie; Dahn, J. R.

doi:10.1149/1945-7111/ac4b83

Cited by 19 publications

(19 citation statements)

References 33 publications

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“…The increasing porosity of particles was hypothesized to cause the irreversible expansion of cells throughout their cycle life by increasing the porosity of electrodes and therefore the volume. 34 The thickness of the NMC electrodes were quantified from the SEM images, however as seen in Fig. 5b the standard deviation of thicknesses measured was too large to confidently determine a trend.…”

Section: Resultsmentioning

confidence: 99%

Quantifying the Impact of Charge Rate and Number of Cycles on Structural Degeneration of Li-Ion Battery Electrodes

Furat¹,

Finegan²,

Yang³

et al. 2022

J. Electrochem. Soc.

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A quantitative link between crack evolution in lithium-ion positive electrodes and the degrading performance on cells is not yet well established nor is any single technique capable of doing so widely available. Here, we demonstrate a widely accessible high-throughput approach to quantifying crack evolution within electrodes. The approach applies super-resolution scanning electron microscopy imaging of cross-sectioned NMC532 electrodes, followed by segmentation and quantification of crack features. Crack properties such as crack intensity, crack width and length are quantified as a function of charge rate (1C, 6C, and 9C) and cycle number (25, 225, and 600 cycles). Hundreds of particles are characterized for statistical confidence in the quantitative crack measurements. The data on crack evolution is compared to electrochemical data from full cells and half cells with the NMC532 positive electrodes. We show that while crack evolution strongly correlates with capacity fade in the first 25 cycles, it does not correlate well for the following hundreds of cycles indicating that cracking may not be the dominant cause of capacity fade throughout the cycle-life of cells.

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Section: Resultsmentioning

confidence: 99%

Quantifying the Impact of Charge Rate and Number of Cycles on Structural Degeneration of Li-Ion Battery Electrodes

Furat¹,

Finegan²,

Yang³

et al. 2022

J. Electrochem. Soc.

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“…For instance, silicon negative electrodes improve the energy density over traditional graphite electrodes in lithium-ion batteries even though they require lower active mass fractions (B90% vs. B96%) and higher porosities (B40% vs. B25%). [68][69][70][71] Fig. 3b also provides correlations for cell performance parameters.…”

Section: Specific Energy Correlation Plotsmentioning

confidence: 99%

From material properties to device metrics: a data-driven guide to battery design

et al. 2023

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“…X-ray CT is the most widespread method for nondestructive testing to identify production-related defects in the battery industry. [30][31][32][33][34][35] The typical implementation in engineering fields utilizes a rotating sample stage between an X-ray tube and a flat panel detector, as illustrated in Figure 2. [36,37] CT measurements with synchrotron radiation are also possible.…”

Section: Ctmentioning

confidence: 99%

Nondestructive Defect Detection in Battery Pouch Cells: A Comparative Study of Scanning Acoustic Microscopy and X‐Ray Computed Tomography

Pitta Bauermann,

Münch,

Kroll

et al. 2023

Energy Tech

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The identification and location of critical defects inside battery cells before the performance decreases or safety issues arise remains a challenge. This study compares two non‐destructive testing methods for the 3D visualization of defects at different depths inside a pouch battery cell: Scanning Acoustic Microscopy (SAM) and X‐ray Computed Tomography (CT). A manufactured pouch cell with 8 electrode sheets is used for this investigation. SAM using a 15 MHz transducer in reflection mode can detect defects at depths of up to four electrode sheets with a lateral resolution of 150 µm in 2 min. CT can locate defects on all eight stacked electrode sheets inside the pouch cell. The CT measurements take about 12.5 h. Both methods can complement each other in detecting defects inside thin pouch cells as an End‐of‐Line test after the production or for qualifying individual battery cells for second‐life applications. As an in‐line quality check, SAM has proven to be a cost‐effective and efficient method for detecting defects such as misalignment on stacked electrodes. Both methods have the potential to expand the portfolio of non‐destructive quality assurance tests in the production of lithium‐ion battery cells. This contributes to increase the safety and productivity of battery technology.This article is protected by copyright. All rights reserved.

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In Situ Imaging of Electrode Thickness Growth and Electrolyte Depletion in Single-Crystal vs Polycrystalline LiNixMnyCozO₂/Graphite Pouch Cells using Multi-Scale Computed Tomography

Cited by 19 publications

References 33 publications

Quantifying the Impact of Charge Rate and Number of Cycles on Structural Degeneration of Li-Ion Battery Electrodes

Quantifying the Impact of Charge Rate and Number of Cycles on Structural Degeneration of Li-Ion Battery Electrodes

From material properties to device metrics: a data-driven guide to battery design

Nondestructive Defect Detection in Battery Pouch Cells: A Comparative Study of Scanning Acoustic Microscopy and X‐Ray Computed Tomography

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In Situ Imaging of Electrode Thickness Growth and Electrolyte Depletion in Single-Crystal vs Polycrystalline LiNixMnyCozO2/Graphite Pouch Cells using Multi-Scale Computed Tomography

Cited by 19 publications

References 33 publications

Quantifying the Impact of Charge Rate and Number of Cycles on Structural Degeneration of Li-Ion Battery Electrodes

Quantifying the Impact of Charge Rate and Number of Cycles on Structural Degeneration of Li-Ion Battery Electrodes

From material properties to device metrics: a data-driven guide to battery design

Nondestructive Defect Detection in Battery Pouch Cells: A Comparative Study of Scanning Acoustic Microscopy and X‐Ray Computed Tomography

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Product

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In Situ Imaging of Electrode Thickness Growth and Electrolyte Depletion in Single-Crystal vs Polycrystalline LiNixMnyCozO₂/Graphite Pouch Cells using Multi-Scale Computed Tomography