Computational Examination of Orientation-Dependent Morphological Evolution during the Electrodeposition and Electrodissolution of Magnesium

DeWitt, Stephen; Hahn, Nathan; Zavadil, Kevin R.; Thornton, Katsuyo

doi:10.1149/2.0781603jes

Cited by 25 publications

(21 citation statements)

References 35 publications

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“…We model a constant applied current by using an iterative bisection scheme to solve at each time step for the cell potential φ applied such that the total current in the cell is within an error tolerance factor of 2.5 × 10 −3 of the target current. 39 Estimates for the cell potential φ applied for the next step are made using linear extrapolation based on the cell potential from the previous and current time steps, and the window of estimated potential input into the bisection algorithm is ±0.0005V . Total current I in the cell is calculated by integrating the normal component of the current density over the area of the cell in a cross-section in the separator just above the anode via I = − κ ef f ∂φ 2 ∂z d A.…”

Section: Discussionmentioning

confidence: 99%

Size Dependence of Transport Non-Uniformities on Localized Plating in Lithium-Ion Batteries

Liu

Fang

Haataja

et al. 2018

J. Electrochem. Soc.

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Plating in lithium-ion batteries not only reduces their lifetime, but also raises safety concerns. Preventing metallic lithium from forming is difficult, as the heterogeneity of materials typically used in batteries can create transport non-uniformities, which can lead to unanticipated local plating. Therefore, being able to predict the occurrence of plating due to a non-uniformity of a certain shape and size becomes essential. In this study, we probe the importance of the size scale and geometry on localized plating through numerical simulations and experiments. Using modified separators to create transport non-uniformities, we show that certain geometric features lead to more vulnerability to plating, and localization strongly depends on size. A single large feature in a separator induces more plating than a collection of smaller features with same total area. Our findings help elucidate the fundamentals behind heterogeneous plating, which can provide practical insights into battery safety and product control.

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Section: Discussionmentioning

confidence: 99%

Size Dependence of Transport Non-Uniformities on Localized Plating in Lithium-Ion Batteries

Liu

Fang

Haataja

et al. 2018

J. Electrochem. Soc.

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“…Liang and Chen 70,84 presented a nonlinear phase-field model, which takes the Butler-Volmer reaction kinetics into account, which can simulate and predict the Li deposit growth during charging processes without considering the SEI layer effect. Enrique et al 85 generalized DeWitt's model to study the morphological evolution of Limetal electrode during electrodeposition 86 . In 2015, Chen et al 87 established a consistent thermodynamic phase-field model to investigate the dendritic patterns, as shown in Fig.…”

Section: Stress Evolution and Fracturementioning

confidence: 99%

Application of phase-field method in rechargeable batteries

Wang

Zhang

et al. 2020

npj Comput Mater

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Rechargeable batteries have a profound impact on our daily life so that it is urgent to capture the physical and chemical fundamentals affecting the operation and lifetime. The phase-field method is a powerful computational approach to describe and predict the evolution of mesoscale microstructures, which can help to understand the dynamic behavior of the material systems. In this review, we briefly introduce the theoretical framework of the phase-field model and its application in electrochemical systems, summarize the existing phase-field simulations in rechargeable batteries, and provide improvement, development, and problems to be considered of the future phase-field simulation in rechargeable batteries.

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“…As in the analytical models, simplifying approximations have commonly been used to improve numerical efficiency, such as electroneutrality of the electrolyte, which may be expressed as ρ = 0, 25,46,50,54,55 or that the current density, i, is solenoidal, ∇ · i = 0. 25,50 Cohen and Cooley 56 presented one of the earliest attempts to solve the PNP equations numerically by assuming electroneutrality and adding a displacement current proportional to the time derivative of the electric field to the expression describing local current density. They then solved the resulting system of equations using an explicit finite difference method (FDM) with a predictor-corrector scheme.…”

Section: Theorymentioning

confidence: 99%

“…Magnesium deposited from organohaloaluminate electrolytes has been observed to nucleate in a hexagonal plate morphology. 4,25 Unfortunately, the available micrographs for Mg(BH 4 ) 2 in tetraglyme only show the deposit morphology well after the initial nucleation process has completed. 24 Thus we assume that magnesium deposits from Mg(BH 4 ) 2 /DME also nucleate as hexagonal plates with a constant ratio between the height and the deposit spacing; as these plates grow, they increasingly cover the WE surface and eventually merge.…”

Section: Model Formulationmentioning

confidence: 99%

“…Additional phase-field models have also been derived in two or three dimensions to examine deposition of copper, 42 lithium, [43][44][45] zinc, 46 and, most recently, magnesium. 25 All of these models have increased scientific understanding of the rich set of phenomena observed during electrodeposition and electrodissolution. Nevertheless, they are commonly limited by high computational cost, which can hinder parameterization efforts as well as the rapid determination of physical properties of materials based on the model results.…”

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confidence: 99%

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Computational Model of Magnesium Deposition and Dissolution for Property Determination via Cyclic Voltammetry

Chadwick

Vardar

DeWitt

et al. 2016

J. Electrochem. Soc.

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The development of a practical magnesium-anode battery requires electrolytes that allow for highly efficient magnesium exchange while also being compatible with cathode materials. Here, a one-dimensional continuum-scale model is developed to simulate cyclic plating/stripping voltammetry of a model magnesium-based electrolyte system employing magnesium borohydride/dimethoxyethane [Mg(BH 4 ) 2 /DME] solutions on a gold substrate. The model is developed from non-electroneutral dilute-solution theory, using Nernst-Planck equations for the mass flux and Poisson's equation for the electrostatic potential. The electrochemical reaction is modeled with multistep Butler-Volmer kinetics, with a modified current/overpotential relationship that separately accounts for the portions of the current responsible for nucleating new deposits and propagating or dissolving existing ones. The diffusivities of the electrolyte species, standard heterogeneous rate constant, charge-transfer coefficient, formal potential, and nucleation overpotential are determined computationally by reproducing experimental voltammograms. The model is computationally inexpensive and therefore allows for broad parametric studies of electrolyte behavior that would otherwise be impractical. A rechargeable magnesium battery was first demonstrated 25 years ago when Gregory et al. 1 showed that magnesium could be reversibly deposited onto and dissolved from a magnesium-metal surface, as well as intercalated into and deintercalated from various host cathodes. Further interest in secondary magnesium batteries arose following the work of Aurbach et al., 2 which demonstrated a highly efficient organohaloaluminate electrolyte using a magnesium anode and a Mo 6 S 8 Chevrel-phase cathode. As a battery anode, magnesium metal offers important advantages over both intercalation compounds and lithium metal, including a higher theoretical volumetric energy capacity (3833 mAh/cm 3 vs. 2046 mAh/cm 3 for lithium metal and 760 mAh/cm 3 for graphite-based lithium-ion anodes), as well as a higher abundance in the earth's crust.3 Additionally, magnesium is less prone to dendrite formation than lithium when electrodeposited and therefore offers potential for improved battery cycle life and safety. 4 In addition to high-capacity electrode materials, a practical magnesium battery will also require an efficient electrolyte that is compatible with (i.e., chemically stable in contact with) these electrodes. Compared to lithium electrolytes, magnesium electrolytes remain in a relatively early developmental stage.1-29 Electrolytes formulated from Grignard reagents have been widely studied both in the battery and general electrochemistry communities. 1,6,28,[30][31][32][33][34][35] The speciation of these electrolytes is complex because, in addition to ionic dissociation, the reagents also undergo the Schlenk equilibrium process (a type of ligand exchange) and form multimeric species in many solvents. Both organohaloaluminates and the so-called magnesium aluminum chloride complex (MACC) a...

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Computational Examination of Orientation-Dependent Morphological Evolution during the Electrodeposition and Electrodissolution of Magnesium

Cited by 25 publications

References 35 publications

Size Dependence of Transport Non-Uniformities on Localized Plating in Lithium-Ion Batteries

Size Dependence of Transport Non-Uniformities on Localized Plating in Lithium-Ion Batteries

Application of phase-field method in rechargeable batteries

Computational Model of Magnesium Deposition and Dissolution for Property Determination via Cyclic Voltammetry

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