Data-driven capacity estimation of commercial lithium-ion batteries from voltage relaxation

Zhu, Jiangong; Wang, Yixiu; Huang, Yuan; Gopaluni, R. Bhushan; Cao, Yankai; Heere, Michael; Mühlbauer, Martin; Mereacre, Liuda; Dai, Haifeng; Liu, Xinhua; Senyshyn, Anatoliy; Wei, Xuezhe; Knapp, Michael; Ehrenberg, Helmut

doi:10.1038/s41467-022-29837-w

Cited by 177 publications

(66 citation statements)

References 52 publications

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“…There have been a few machine-learning based methods developed in the literature including the automatic capacity estimation of lithium-ion batteries. [31] To systematically predict the performance degradation behavior of battery material it requires enough dataset collected under different operational conditions. Scientifically, it is…”

Section: Discussionmentioning

confidence: 99%

Deep‐Learning‐Enabled Crack Detection and Analysis in Commercial Lithium‐Ion Battery Cathodes

Monaco

et al. 2022

Adv Funct Materials

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In Li-ion batteries, the mechanical degradation initiated by micro cracks is one of the bottlenecks for enhancing the performance. Quantifying the crack formation and evolution in complex composite electrodes can provide important insights into electrochemical behaviors under prolonged and/or aggressive cycling. However, observation and interpretation of the complicated crack patterns in battery electrodes through imaging experiments are often timeconsuming, labor intensive, and subjective. Herein, a deep learning-based approach is developed to extract the crack patterns from nanoscale hard X-ray holo-tomography data of a commercial 18650-type battery cathode. Efficient and effective quantification of the damage heterogeneity with automation and statistical significance is demonstrated. The crack characteristics are further associated with the active particles' packing densities and a potentially viable architectural design is discussed for suppressing the structural degradation in an industry-relevant battery configuration.

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Section: Discussionmentioning

confidence: 99%

Deep‐Learning‐Enabled Crack Detection and Analysis in Commercial Lithium‐Ion Battery Cathodes

Monaco

et al. 2022

Adv Funct Materials

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“…where α i is Lagrange multiplier. And α Ã can be acquired by Equation ( 9), and ω can be calculated by Equation (10). b can be derived using any single support vector after the calculation of the optimal ω.…”

Section: Svmmentioning

confidence: 99%

“…Robert et al [8b] estimated the battery capacity by using the time series values at equispaced voltages extracted from the voltage versus time curves; ≈2–3% RMSE was achieved with a 10 s galvanostatic operation. Our previous work [ 10 ] used the features extracted from the relaxation voltage curve after being fully charged for battery capacity estimation, and the best RMSE of 1.1% is obtained. Besides the charging and discharging voltage data, alternating current (AC) impedance is also served as an important input feature for battery state estimation, [ 11 ] e.g., temperature estimation, [11c] and SoH investigation [2b,12] with high potential of onboard implementations.…”

Section: Introductionmentioning

confidence: 99%

Alternating Current Impedance Probing Capacity of Lithium‐Ion Battery by Gaussian Process Regression

et al. 2022

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Alternating current (AC) impedance is an important and promising feature for lithium‐ion battery state estimation and prediction. Herein, a new battery capacity estimation method using AC impedance with Gaussian process regression (GPR) is proposed. A bunch of high‐energy 18 650‐type batteries with a nominal capacity of 3.5 Ah are cycled at 25, 35, and 45 °C until the capacity drops below 2.6 Ah. Two single‐frequency points are found which are highly correlated with the battery residual capacity regardless of the cycling temperatures. Machine learning methods are used to probe the battery capacity with the real and imaginary impedance of two single‐frequency points. The best model achieves a test root‐mean‐squared error of 0.5% (17.36 mAh) with GPR. This work provides a new perspective to predicting the complex dynamical behavior of batteries by combining electrochemical impedance with data‐driven methods.

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“…A rechargeable Li battery based on the Li chemistry is considered a promising candidate for battery systems and related functions. Typically, lithium-sulfur batteries (LSBs) are selected as ideal choices for energy storage systems due to their high theoretical-specific capacity (1,672 mA h/g) and theoretical-specific energy density (2,600 W h/kg), which is five times higher than traditional lithium-ion batteries (LIBs) (Dai et al, 2021;Zhou et al, 2021;Zhu et al, 2022). Meanwhile, compared to the lithium-ion battery, elemental sulfur, the main active material in LSBs, has the advantages of being abundantly stored, low-cost, simple to prepare, and environmentally friendly (Li et al, 2019;Gong and Wang, 2020;Liu X.-Z.…”

Section: Introductionmentioning

confidence: 99%

Recent Progress in Quasi/All-Solid-State Electrolytes for Lithium–Sulfur Batteries

et al. 2022

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Lithium–sulfur batteries have received increasing research interest due to their superior theoretical capacity, cost-effectiveness, and eco-friendliness. However, the commercial realization of lithium–sulfur batteries faces critical obstacles, such as the significant volume change of sulfur cathodes over the de/lithiation processes, uncontrollable shuttle effects of polysulfides, and the lithium dendrite issue. On this basis, the lithium–sulfur battery based on solid-state electrolytes was developed to alleviate the previously mentioned problems. This article aims to provide an overview of the recent progress of solid-state lithium–sulfur batteries related to various kinds of solid-state electrolytes, which mainly include three aspects: the fundamentals and current status of lithium–sulfur solid-state batteries and several adopted solid-state electrolytes involving polymer electrolyte, inorganic solid electrolyte, and hybrid electrolyte. Furthermore, the future perspective for lithium–sulfur solid-state batteries is presented. Finally, this article proposed an initiation for new and practical research activities and paved the way for the design of usable lithium–sulfur solid-state batteries.

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Data-driven capacity estimation of commercial lithium-ion batteries from voltage relaxation

Cited by 177 publications

References 52 publications

Deep‐Learning‐Enabled Crack Detection and Analysis in Commercial Lithium‐Ion Battery Cathodes

Deep‐Learning‐Enabled Crack Detection and Analysis in Commercial Lithium‐Ion Battery Cathodes

Alternating Current Impedance Probing Capacity of Lithium‐Ion Battery by Gaussian Process Regression

Recent Progress in Quasi/All-Solid-State Electrolytes for Lithium–Sulfur Batteries

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