Your search keyword '"Ghamlouche, Yara"' showing total 4 results

1. Control of Dendrites in Rechargeable Batteries using Smart Charging

Author

Aryanfar, Asghar, Ghamlouche, Yara, and Goddard III, William A.

Subjects

Physics - Chemical Physics, Physics - Applied Physics

Abstract

In this paper we develop a feed-back control framework for the real-time minimization of microstructures grown within the rechargeable battery. Due to quickening nature of the branched evolution, we identify the critical ramified peaks in the early stages and based on the state we compute the relaxation time for the concentration in those branching fingers. The control parameter is a function of the maximum curvature (i.e. minimum radius) of the branched microstructure, where the higher rate dendritic evolution would lead to the more critical state to be controlled. The charging time is minimized for generating the most packed microstructures and obtained results correlate closely with those of considerably higher charging time periods. The developed framework could be utilized as a smart charging protocol for the safe and sustainable operation the rechargeable batteries, where the branching of the microstructures could be correlated to the sudden variation in the current/voltage., Comment: 17 pages, 14 figures.arXiv admin note: text overlap with arXiv:1908.02362

Published

2020

2. Optimization of charge curve for the extreme inhibition of growing microstructures during electrodeposition

Author

Aryanfar, Asghar, Ghamlouche, Yara, and Goddard, III, William A.

Published

2022

3. Pulse Reverse Protocol for efficient suppression of dendritic micro-structures in rechargeable batteries

Author

Aryanfar, Asghar, Ghamlouche, Yara, and Goddard III, William A.

Published

2021

4. Real-time control of dendritic propagation in rechargeable batteries using adaptive pulse relaxation.

Author

Aryanfar, Asghar, Ghamlouche, Yara, and Goddard III, William A.

Subjects

*REAL-time control, *STORAGE batteries, *LITHIUM-ion batteries, *CURVATURE, *SQUARE waves

Abstract

The non-uniform growth of microstructures in dendritic form inside the battery during prolonged charge–discharge cycles causes short-circuit as well as capacity fade. We develop a feedback control framework for the real-time minimization of such microstructures. Due to the accelerating nature of the branched evolution, we focus on the early stages of growth, identify the critical ramified peaks, and compute the effective time for the dissipation of ions from the vicinity of those branching fingers. The control parameter is a function of the maximum interface curvature (i.e., minimum radius) where the rate of runaway is the highest. The minimization of the total charging time is performed for generating the most packed microstructures, which correlate closely with those of considerably higher charging periods, consisting of constant and uniform square waves. The developed framework could be utilized as a smart charging protocol for safe and sustainable operation of rechargeable batteries, where the branching of the microstructures could be correlated with the sudden variation in the current/voltage. [ABSTRACT FROM AUTHOR]

Published

2021