Lithium-Ion Battery Degradation: Measuring Rapid Loss of Active Silicon in Silicon–Graphite Composite Electrodes

Kirkaldy, Niall; Samieian, Mohammad Amin; Offer, Gregory J.; Marinescu, Monica; Patel, Yatish

doi:10.1021/acsaem.2c02047

Cited by 33 publications

(12 citation statements)

References 43 publications

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“…These results also show that SiOx electrochemical activity is decreased for the cells that are cycled down to 0% SoC such as R0-50, H0-50, R0-100, and H0-100 (Figure 3 b, c, f, g). This trend is expected as SiOx is known to degrade at cell potentials below 50% SoC [79]. On the contrary, the positive electrode degradation is anticipated at potentials corresponding to ≥50% SoC due to lower stability of the positive electrode upon delithiation [80].…”

Section: Discussionmentioning

confidence: 95%

“…𝑄 Si = 𝑄 𝑑 − 𝑄 N3 − 𝜃 𝑐 ⋅ 𝑄 Gr The necessary assumption in this estimation is that both the silicon and graphite are fully delithiated following the 0.1C step to 1.5 V. Effectively, this resolves the silicon amount that is kinetically available, which may be somewhat less than the total silicon content determined by other techniques. In spirit, this method of separating the silicon contribution is the same as can be done with fitting the open circuit potential for blended electrodes [79]. However, this manual algebraic calculation provides simplified, quick quantification in concert with the analysis of the differential voltage profiles.…”

Section: Detailed Analysis Of the Degradation Of The Negative Electrodementioning

confidence: 99%

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Ageing of High Energy Density Automotive Li-ion Batteries: The Effect of Temperature and State-of-Charge

Mikheenkova

Smith

Frenander

et al. 2023

Preprint

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Lithium ion batteries (LIB) have become a cornerstone of the shift to electric transportation. In an attempt to decrease the production load and prolong battery life, understanding different degradation mechanisms in state-of-the-art LIBs is essential. Here, we analyze how operational temperature and state-of-charge (SoC) range in cycling influence the ageing of automotive grade 21700 batteries, extracted from a Tesla 3 Long Range 2018 battery pack with positive electrode containing LiNixCoyAlzO2 (NCA) and negative electrode containing SiOx-C. In the given study we use a combination of electrochemical and material analysis to understand degradation sources in the cell. Herein we show that loss of lithium inventory is the main degradation mode in the cells, with loss of material on the negative electrode as there is a significant contributor when cycled in the low SoC range. Degradation of NCA dominates at elevated temperatures with combination of cycling to high SoC (beyond 50%).

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Section: Discussionmentioning

confidence: 95%

Section: Detailed Analysis Of the Degradation Of The Negative Electrodementioning

confidence: 99%

Ageing of High Energy Density Automotive Li-ion Batteries: The Effect of Temperature and State-of-Charge

Mikheenkova

Smith

Frenander

et al. 2023

Preprint

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“…This expansion leads to the decomposition and reconstruction of the SEI layer, thereby consuming more lithium. 9,48,50,51 At a higher SoC range, the graphite dominates the aging behavior, which can be seen by the similar capacity loss regardless of SiOx content in the cells.…”

Section: ιιmentioning

confidence: 94%

Cycle Characterization of SiO-Based Lithium-Ion-Batteries Using Real Load Profiles

Moyassari,

Li,

Tepe

et al. 2023

J. Electrochem. Soc.

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Understanding the cyclic behavior of Lithium-Ion Batteries (LIBs) is crucial for optimizing their performance and extending their operational lifespan. This work presents a study on the cycle characterization of silicon-oxide-based (SiOx) cells, focusing on the impact of real load profiles and state-of-charge (SoC) ranges while varying the SiOx content in the cells. Various load profiles representing real usage patterns obtained from an industrial partner were applied to SiO-based pouch cells. These load profiles are represented over different SoC ranges to explore the effect of varying levels of charge/discharge on battery aging. The aging characteristics of the batteries are evaluated by monitoring capacity fade, state-of-health (SoH), and capacity end-point-slippage. The experimental results demonstrate that the different SiOx content of the investigated cells and the SoC range significantly influence the cycle behavior of the cells. The resulting capacity loss was affected especially by the anode overhang effect. Cycling under high SoC conditions accelerates capacity fade and leads to higher SoH loss. The findings also indicate that SiO-based cells exhibited higher aging than traditional graphite-based cells. The capacity fade rate increased at higher SiOx content.

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“…[52] Kirkaldy et al observed that the LAM of active Si was greater than that of graphite at low SOC and high temperatures. [62] Zhang et al discovered that the dissolution of transition metals (TMs) was more detrimental to Si than to graphite. [63] The LAM PE is highly dependent on different cathode chemistries.…”

Section: Loss Of Active Materials (Lam)mentioning

confidence: 99%

Accurate Model Parameter Identification to Boost Precise Aging Prediction of Lithium‐Ion Batteries: A Review

Ding,

Li,

Dai

et al. 2023

Advanced Energy Materials

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Precise prediction of lithium‐ion cell level aging under various operating conditions is an imperative but challenging part of ensuring the quality performance of emerging applications such as electric vehicles and stationary energy storage systems. Accurate and real‐time battery‐aging prediction models, which require an exact understanding of the degradation mechanisms of battery components and materials, could in turn provide new insights for materials and battery basic research. Furthermore, the primary barrier to meaningful artificial intelligence/machine learning for accelerating the prediction period is the exploitation of accurate aging mechanistic descriptors. This review comprehensively summarizes the evolution of deterioration mechanisms at the material and cell level in different environments and usage scenarios, including the intricate relationships between aging mechanisms, degradation modes, and external influences, which are the cornerstones of modeling simulation and machine learning techniques. Recent advances in electrochemical models coupled with internal battery degradation mechanisms as well as identification and tracking of aging parameters are shown, with particular emphasis on electrode balance and the anticipated trend of machine learning‐assisted reliable remaining useful life prediction. Precise simulation prediction of cell level aging will continue to play an essential role in advanced smart battery research and management, enhancing its performance while shortening experimental sequences.

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Lithium-Ion Battery Degradation: Measuring Rapid Loss of Active Silicon in Silicon–Graphite Composite Electrodes

Cited by 33 publications

References 43 publications

Ageing of High Energy Density Automotive Li-ion Batteries: The Effect of Temperature and State-of-Charge

Ageing of High Energy Density Automotive Li-ion Batteries: The Effect of Temperature and State-of-Charge

Cycle Characterization of SiO-Based Lithium-Ion-Batteries Using Real Load Profiles

Accurate Model Parameter Identification to Boost Precise Aging Prediction of Lithium‐Ion Batteries: A Review

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