Pulse Polarization for Li-Ion Battery under Constant State-of-Charge: Part II. Modeling of Individual Voltage Losses and SOC Prediction

DuBeshter, Tyler; Jorné, Jacob

doi:10.1149/2.0421711jes

Cited by 5 publications

(1 citation statement)

References 24 publications

(82 reference statements)

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“…While the GITT/PITT are able to determine diffusion in electrodes using half cells, our method can be more readily applied to many rechargeable commercial cells for performance evaluation and metrics. In a subsequent paper 46,47 we utilized Newman's method to simulate the pulse discharge experiments and to extend the pulse time to 2-240 seconds in order to investigate steady state polarizations when all Lithium gradients are fully developed under constant SOC.…”

Section: Experimental Methods For Pulse Polarization Curve Constructionmentioning

confidence: 99%

Pulse Polarization for Li-Ion Battery under Constant State of Charge: Part I. Pulse Discharge Experiments

DuBeshter

Jorné

2017

J. Electrochem. Soc.

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Given the increased dependence on battery-powered devices, it is necessary to develop new and robust methods to evaluate and predict battery performance and state of charge. Batteries, including Li-Ion batteries, are unsteady state systems and a need exists to evaluate performance under constant state of charge (SOC). The purpose of this work was to develop pulse polarization curves (PPC) for a Li-Ion battery under constant SOC in order to identify individual overvoltages, such as charge transfer kinetics and mass transport, and their SOC dependence. Consequently, we elected to conduct pulse discharges at various duration and discharge current densities, under well maintained SOCs. Based on the results we were able to construct pulse polarization curves for constant SOCs of 10, 40 and 70% at various pulse durations of 2, 10 and 30 seconds. The experimentally obtained pulse polarizations suggest that the kinetic overpotential is captured in the 2 second pulse, while electrolyte Li+ concentration and Li solid state diffusion gradients are established in the 10 and 30 second pulse times, respectively. This allowed us to identify the individual overvoltages experimentally. An important consideration was that as the battery's SOC changes, the open circuit voltage (OCV) also changes. Therefore, the pulse discharge method we used needed to end at the same SOC in all cases to enable the construction of a PPC with the same OCV. To ensure that this method applied to various sizes and chemistries of batteries reliably, we ran pulse discharge experiments on a high Amp hour (15 Ah) large Li-Ion pouch battery (power) that used a NMC LMO cathode, as well as on a low Amp hour (0.04 Ah) small electrode coin battery (energy) with a CoO 2 cathode. In a subsequent paper we employed the Newman method to model the pulse discharges, allowing prediction of the performance of Li-Ion batteries and constructing their PPCs under constant SOC.

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Section: Experimental Methods For Pulse Polarization Curve Constructionmentioning

confidence: 99%

Pulse Polarization for Li-Ion Battery under Constant State of Charge: Part I. Pulse Discharge Experiments

DuBeshter

Jorné

2017

J. Electrochem. Soc.

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A semi-empirical, electrochemistry-based model for Li-ion battery performance prediction over lifetime

Varini

Campana

Lindbergh

2019

Journal of Energy Storage

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Nondestructive measurement method for the differentiation of entropy evolution and aging contributions of the electrode of a lithium battery using a comparative thermodynamic analysis

et al. 2020

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Pulse Polarization for Li-Ion Battery under Constant State-of-Charge: Part II. Modeling of Individual Voltage Losses and SOC Prediction

Cited by 5 publications

References 24 publications

Pulse Polarization for Li-Ion Battery under Constant State of Charge: Part I. Pulse Discharge Experiments

Pulse Polarization for Li-Ion Battery under Constant State of Charge: Part I. Pulse Discharge Experiments

A semi-empirical, electrochemistry-based model for Li-ion battery performance prediction over lifetime

Nondestructive measurement method for the differentiation of entropy evolution and aging contributions of the electrode of a lithium battery using a comparative thermodynamic analysis

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