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

Chadwick, Alexander F.; Vardar, Gulin; DeWitt, Stephen; Sleightholme, Alice E.S.; Monroe, Charles W.; Siegel, Donald J.; Thornton, Katsuyo

doi:10.1149/2.0031609jes

Cited by 22 publications

(25 citation statements)

References 68 publications

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“…28 The numerical model solves the time-based evolution of the Poisson–Nernst–Planck system of equations (PNP equations) to describe the electrochemical mass transport and the electrostatic potential across the cell. In 1D, the Nernst–Planck equation takes the formwhere J i is the mass flux of the i th species, D i is the diffusivity of the species, z i and c i are the charge and concentration of the i th species, x is the position, F is Faraday’s constant, R is the ideal gas constant, T is the absolute temperature, and ϕ is the electrostatic potential.…”

Section: Numerical Modelmentioning

confidence: 99%

“…To provide a theoretical description of the cell behavior, a onedimensional (1D) numerical continuum-scale model was developed based on previous efforts to study the deposition and dissolution of magnesium metal anodes. 28 The numerical model solves the time-based evolution of the Poisson−Nernst− Planck system of equations (PNP equations) to describe the electrochemical mass transport and the electrostatic potential across the cell. In 1D, the Nernst−Planck equation takes the form…”

Section: Numerical Modelmentioning

confidence: 99%

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Dendrites and Pits: Untangling the Complex Behavior of Lithium Metal Anodes through Operando Video Microscopy

et al. 2016

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Enabling ultra-high energy density rechargeable Li batteries would have widespread impact on society. However the critical challenges of Li metal anodes (most notably cycle life and safety) remain unsolved. This is attributed to the evolution of Li metal morphology during cycling, which leads to dendrite growth and surface pitting. Herein, we present a comprehensive understanding of the voltage variations observed during Li metal cycling, which is directly correlated to morphology evolution through the use of operando video microscopy. A custom-designed visualization cell was developed to enable operando synchronized observation of Li metal electrode morphology and electrochemical behavior during cycling. A mechanistic understanding of the complex behavior of these electrodes is gained through correlation with continuum-scale modeling, which provides insight into the dominant surface kinetics. This work provides a detailed explanation of (1) when dendrite nucleation occurs, (2) how those dendrites evolve as a function of time, (3) when surface pitting occurs during Li electrodissolution, (4) kinetic parameters that dictate overpotential as the electrode morphology evolves, and (5) how this understanding can be applied to evaluate electrode performance in a variety of electrolytes. The results provide detailed insight into the interplay between morphology and the dominant electrochemical processes occurring on the Li electrode surface through an improved understanding of changes in cell voltage, which represents a powerful new platform for analysis.

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Section: Numerical Modelmentioning

confidence: 99%

Section: Numerical Modelmentioning

confidence: 99%

Dendrites and Pits: Untangling the Complex Behavior of Lithium Metal Anodes through Operando Video Microscopy

et al. 2016

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“…In the case of magnesium and DME based chloride‐free electrolytes the cathodic symmetry factor seems to be significantly smaller than 0.5. [39] Consequently, the transition state during plating from DME solvated magnesium cations is more reactant‐ than product‐like, which indicates that the desolvation plays an important role during the magnesium deposition. Therefore, the solvent (and anion) might significantly influence the symmetry factor of the Butler‐Volmer kinetics.…”

Section: Introductionmentioning

confidence: 99%

Modeling of Electron‐Transfer Kinetics in Magnesium Electrolytes: Influence of the Solvent on the Battery Performance

et al. 2021

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The performance of rechargeable magnesium batteries is strongly dependent on the choice of electrolyte. The desolvation of multivalent cations usually goes along with high energy barriers, which can have a crucial impact on the plating reaction. This can lead to significantly higher overpotentials for magnesium deposition compared to magnesium dissolution. In this work we combine experimental measurements with DFT calculations and continuum modelling to analyze Mg deposition in various solvents. Jointly, these methods provide a better understanding of the electrode reactions and especially the magnesium deposition mechanism. Thereby, a kinetic model for electrochemical reactions at metal electrodes is developed, which explicitly couples desolvation to electron transfer and, furthermore, qualitatively takes into account effects of the electrochemical double layer. The influence of different solvents on the battery performance is studied for the state-of-the-art magnesium tetrakis(hexafluoroisopropyloxy)borate electrolyte salt. It becomes apparent that not necessarily a whole solvent molecule must be stripped from the solvated magnesium cation before the first reduction step can take place. For Mg reduction it seems to be sufficient to have one coordination site available, so that the magnesium cation is able to get closer to the electrode surface. Thereby, the initial desolvation of the magnesium cation determines the deposition reaction for mono-, tri-and tetraglyme, whereas the influence of the desolvation on the plating reaction is minor for diglyme and tetrahydrofuran. Overall, we can give a clear recommendation for diglyme to be applied as solvent in magnesium electrolytes.

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“…Rechargeable magnesium (Mg) batteries have been regarded as one of the promising candidates to power future electric vehicles and support large-scale energy storage systems owing to the high theoretical volumetric capacity (3832 mA h cm –3 for the Mg metal anode vs 2062 mA h cm –3 for the Li metal anode), low cost, and large natural abundance of Mg. − Mg batteries might also raise less safety concerns because the electrochemical deposition of Mg does not involve the formation of either thick solid electrolyte interface layers or metallic dendrites. − However, the commercialization of such promising batteries has not yet been realized because of the unsatisfied properties of Mg-ion electrolytes, including the poor compatibility with cathode materials, insufficient electrochemical window, and undesired Mg plating/stripping properties. − …”

Section: Introductionmentioning

confidence: 99%

Multifunctional Additives Improve the Electrolyte Properties of Magnesium Borohydride Toward Magnesium–Sulfur Batteries

Zhang

Qiao

et al. 2018

ACS Appl. Mater. Interfaces

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Highly reductive magnesium borohydride [Mg(BH)] is compatible with metallic Mg, making it a promising Mg-ion electrolyte for rechargeable Mg batteries. However, pure Mg(BH) in ether-based solutions displays very limited solubility (0.01 M), low oxidative stability (<1.8 V vs Mg), and nucleophilic characteristic, all of which preclude its practical utilization for any battery applications. Herein, we present a multifunctional additive of tris(2 H-hexafluoroisopropyl)borate (THFPB) for preparing Mg(BH)-based electrolytes. By virtue of the strong electron-acceptor ability of the THFPB molecule, a transparent and high-concentration Mg(BH)/THFPB-diglyme (DGM) electrolyte (0.5 M, almost 50 times higher than that of the pristine Mg(BH)-DGM electrolyte) is first obtained, which shows dramatic performance improvements, including high ionic conductivity (3.72 mS cm at 25 °C) and high Mg plating/stripping Coulombic efficiency (>99%). The newly-generated active cation and anion species revealed by Raman, NMR and MS spectra, increase the electrochemical potential window from 1.8 V to 2.8 V vs Mg on stainless steel electrode, rendering electrolytes the ability to examine high voltage cathodes. More importantly, on account of the non-nucleophilicity of active electrolyte species, we present the first example of magnesium-sulfur (Mg-S) batteries using Mg(BH)-based electrolytes, which exhibit a high discharge capacity of 955.9 and 526.5 mA h g at the initial and 30th charge/discharge cycles, respectively. These achievements not only provide an efficient and specific strategy to eliminate the major roadblocks facing Mg(BH)-based electrolytes but also highlight the profound effect of functional additives on the electrochemical performances of unsatisfied Mg-ion electrolytes.

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

Cited by 22 publications

References 68 publications

Dendrites and Pits: Untangling the Complex Behavior of Lithium Metal Anodes through Operando Video Microscopy

Dendrites and Pits: Untangling the Complex Behavior of Lithium Metal Anodes through Operando Video Microscopy

Modeling of Electron‐Transfer Kinetics in Magnesium Electrolytes: Influence of the Solvent on the Battery Performance

Multifunctional Additives Improve the Electrolyte Properties of Magnesium Borohydride Toward Magnesium–Sulfur Batteries

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