Insights into the Morphological Evolution of Mossy Dendrites in Lithium Metal Symmetric and Full Cell: A Modelling Study

Verma, Prakhar; Puravankara, Sreeraj; Nandanwar, Mahendra Naktuji; Chakraborty, Jayanta

doi:10.1149/1945-7111/acc211

Cited by 3 publications

(2 citation statements)

References 69 publications

(91 reference statements)

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“…In recent years, advances in characterization techniques and theoretical methods have allowed researchers to make various experimental and theoretical calculations [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

“…Yurkiv et al [22] considered the influence of the solid electrolyte interface on lithium dendrites, and the study showed that reducing the stress field at the root of lithium dendrites could inhibit the growth of lithium dendrites. In recent years, advances in characterization techniques and theoretical methods have allowed researchers to make various experimental and theoretical calculations [9][10][11]. There is strong scholarly interest in the stability of the lithium anode and the growth mechanism and morphology of the lithium dendrite, and a method of inhibiting the dendrite is proposed [12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

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Analysis of Pressure Characteristics of Ultra-High Specific Energy Lithium Metal Battery for Flying Electric Vehicles

Shi,

Chai,

2024

Electronics

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The lithium metal battery is likely to become the main power source for the future development of flying electric vehicles for its ultra-high theoretical specific capacity. In an attempt to study macroscopic battery performance and microscopic lithium deposition under different pressure conditions, we first conduct a pressure cycling test proving that amplifying the initial preload can delay the battery failure stage, and the scanning electron microscope (SEM) shows that the pressure is effective in improving the electrode’s surface structure. Secondly, we analyze how differing pressure conditions affect the topography of lithium deposits by coupling the nonlinear phase-field model with the force model. The results show that the gradual increase in the external pressure is accompanied by a drop in the length of the dendrite and the migration curvature in the diaphragm, and the deposition morphology is gradually geared towards smooth and thick development, which can significantly reduce the specific surface area of lithium dendrite. However, as cyclic charging and discharging continue, the decrease in the electrolyte diffusion coefficient results in higher internal stress inside the battery, and thus the external pressure must be increased so as to achieve marked inhibitory effects on the growth of the lithium dendrite.

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“…In recent years, advances in characterization techniques and theoretical methods have allowed researchers to make various experimental and theoretical calculations [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Analysis of Pressure Characteristics of Ultra-High Specific Energy Lithium Metal Battery for Flying Electric Vehicles

Shi,

Chai,

2024

Electronics

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Simulations of dendrite and crack and their interactions in solid electrolyte by phase field method

Jiang,

Wang,

et al. 2024

Journal of Energy Storage

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Combination of a Phase-Field Model with Nucleation Kinetics to Simulate Lithium Dendrite Growth

Verma,

Puravankara,

Chakraborty

2024

J. Phys. Chem. C

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The nonuniform deposition of lithium at the current collector severely hinders the development of anode-free lithium metal batteries. The morphology of such electrodeposition relies on the nucleation and growth kinetics at the electrochemical interface. Although dendritic growth remains a subject of extensive research, nucleation of lithium metal on the current collector surface remains relatively unexplored. In this article, a phase-field model will be coupled with classical nucleation theory to understand the interactions between nucleation and growth dynamics. The simulation explores the effect of overpotential on the growth morphology at slow and fast nucleation kinetics by varying the preexponential kinetic factor. At low values of the pre-exponential factor, lithium nucleation is highly dependent on the overpotential. Poor current collector surface coverage and columnar dendrite morphology are common features of such depositions. On the other hand, a high pre-exponential factor results in denser deposits and complete coverage of the current collector surface. As expected, this model shows that, in general, dendritic growth occurs at a high overpotential. This model also opens an avenue where optimization of various factors such as surface energy, additives, and operating parameters may be explored theoretically.

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Insights into the Morphological Evolution of Mossy Dendrites in Lithium Metal Symmetric and Full Cell: A Modelling Study

Cited by 3 publications

References 69 publications

Analysis of Pressure Characteristics of Ultra-High Specific Energy Lithium Metal Battery for Flying Electric Vehicles

Analysis of Pressure Characteristics of Ultra-High Specific Energy Lithium Metal Battery for Flying Electric Vehicles

Simulations of dendrite and crack and their interactions in solid electrolyte by phase field method

Combination of a Phase-Field Model with Nucleation Kinetics to Simulate Lithium Dendrite Growth

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