Biblio
Found 44 results
The Application of Data-Driven Methods and Physics-Based Learning for Improving Battery Safety. Joule. 5(2):316-329.
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2021. End-of-life or second-life options for retired electric vehicle batteries. Cell Reports Physical Science. 2(8)
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2021. Guiding the Design of Heterogeneous Electrode Microstructures for Li‐Ion Batteries: Microscopic Imaging, Predictive Modeling, and Machine Learning. Advanced Energy Materials. 11(19)
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2021. Large-deformation plasticity and fracture behavior of pure lithium under various stress states. Acta Materialia. 208
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2021. A physics-guided neural network framework for elastic plates: comparison of governing equations-based and energy-based approaches. Computer Methods in Applied Mechanics and Engineering. 383:113933.
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2021. .
2021. Strain Rate Dependent Plasticity of Lithium-ion Pouch Cells: Experiments and Simulations. International Journal of Impact Engineering. 159
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2021. A large deformation and fracture model of lithium-ion battery cells treated as a homogenized medium. Journal of The Electrochemical Society. 167(12)
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2020. Mechanical Deformation of Lithium-Ion Pouch Cells under In-Plane Loads—Part I: Experimental Investigation. Journal of The Electrochemical Society. 167
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2020. Mechanical Deformation of Lithium-Ion Pouch Cells under in-plane Loads—Part II: Computational Modeling. Journal of the Electrochemical Society. 167
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2020. Microstructural deformation patterns of a highly orthotropic polypropylene separator of lithium-ion batteries: Mechanism, model, and theory. Extreme Mechanics Letters. 37
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2020. Microstructure reconstruction of battery polymer separators by fusing 2D and 3D image data for transport property analysis. Journal of Power Sources. 480
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2020. Data-Driven Safety Envelope of Lithium-Ion Batteries for Electric Vehicles. Joule. 3(11):2703-2715.
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2019. Deformation and failure of lithium-ion batteries treated as a discrete layered structure. International Journal of Plasticity. 121:293-311.
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2019. Dynamic impact response of lithium-ion batteries, constitutive properties and failure model. RSC advances. 9(5):2464-2473.
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2019. Elliptical lithium‐ion batteries: Transverse and axial loadings under wet/dry conditions. Energy Science & Engineering.
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2019. Mechanical failure of lithium-ion batteries. Mechanical Engineering. Ph.D.
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2019. Mechanism of strengthening of battery resistance under dynamic loading. International Journal of Impact Engineering. 131:78-84.
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2019. Prediction of shear crack formation of Lithium-ion batteries under rod indentation: Comparison of seven failure criteria. Engineering Fracture Mechanics. 217
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2019. Adhesion strength of the cathode in lithium-ion batteries under combined tension/shear loadings. RSC advances. 8(8):3996-4005.
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2018. Comparative study of mechanical-electrical-thermal responses of pouch, cylindrical, and prismatic lithium-ion cells under mechanical abuse. Science China Technological Sciences. 61(10):1472–1482.
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2018. Effects of electrolyte, loading rate and location of indentation on mechanical integrity of li-ion pouch cells. Journal of Power Sources. 396:412-420.
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2018. Failure in lithium-ion batteries under transverse indentation loading. Journal of Power Sources. 389:148-159.
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2018. Investigation of the deformation mechanisms of lithium-ion battery components using in-situ micro tests. Applied Energy. 224:251-266.
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2018. A review of safety-focused mechanical modeling of commercial lithium-ion batteries. Journal of Power Sources. 378:153-168.
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2018.