A Model for Predicting Capacity Fade due to SEI Formation in a Commercial Graphite/LiFePO<sub>4</sub>Cell

Ekström, Henrik; Lindbergh, Göran

doi:10.1149/2.0641506jes

Cited by 141 publications

(101 citation statements)

References 23 publications

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“…61,62 As we only assume a new formation without dissolution by cracking, the anodic part in the Butler-Volmer equation is omitted and the overpotential η crack considers no i R-drop.…”

Section: Model Developmentmentioning

confidence: 99%

A SEI Modeling Approach Distinguishing between Capacity and Power Fade

Kindermann

Keil

Frank

et al. 2017

J. Electrochem. Soc.

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In this paper we introduce a pseudo two-dimensional (P2D) model for a common lithium-nickel-cobalt-manganese-oxide versus graphite (NCM/graphite) cell with solid electrolyte interphase (SEI) growth as the dominating capacity fade mechanism on the anode and active material dissolution as the main aging mechanism on the cathode. The SEI implementation considers a growth due to non-ideal insulation properties during calendar as well as cyclic aging and a re-formation after cyclic cracking of the layer during graphite expansion. Additionally, our approach distinguishes between an electronic (σ SEI ) and an ionic (κ SEI ) conductivity of the SEI. This approach introduces the possibility to adapt the model to capacity as well as power fade. Simulation data show good agreement with an experimental aging study for NCM/graphite cells at different temperatures introduced in literature. © The Author Lithium-ion batteries are one of the most promising candidates for energy storage in future stationary storage systems and electric vehicles.1-3 Enormous research efforts have been conducted to get a thorough understanding of the system "lithium-ion cell" and to further develop it for higher energy and power density, higher safety standards as well as longer cycle life. 4 The aging behavior of lithium-ion batteries has been a focus issue of battery research since the introduction of lithium-ion cells by Sony in 1991. 5 Reviews by Agubra et al., 6,7 Arora et al., 8 Aurbach et al., 9,10 Birkl et al., 11 Broussely et al., 12 Verma et al. 13 and Vetter et al. 14 are just a few examples of the extensive literature regarding aging behavior. Commonly accepted and experimentally verified aging phenomena as mentioned in the previously cited literature are electrolyte decomposition leading to solid electrolyte interphase (SEI) and cathode electrolyte interphase (CEI) growth, solvent co-intercalation, gas evolution with subsequent cracking of particles, a decrease of accessible surface area and porosity due to SEI growth, contact loss of active material particles due to volume changes during cycling, binder decomposition, current collector corrosion, metallic lithium plating and transition-metal dissolution from the cathode. The listed aging mechanisms can be assigned to three different categories that are a loss of lithium-ions (LLI), an impedance increase and a loss of active material (LAM). 12,[15][16][17][18] The LLI is synonymous to a decrease in the amount of cyclable lithium-ions as they are trapped in a passivating film on either of the electrodes or in plated metallic lithium. Due to the growth of the passivating layers and/or the formation of rock-salt in the cathode (residue of the cathode active material after transition-metal dissolution), kinetic transport of lithium-ions through those inactive areas is limited and results in an impedance rise. An LAM can be caused by the dissolution of transition-metal-ions from the cathode bulk material, changes in the electrode composition and/or changes in crystal structure of the a...

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“…61,62 As we only assume a new formation without dissolution by cracking, the anodic part in the Butler-Volmer equation is omitted and the overpotential η crack considers no i R-drop.…”

Section: Model Developmentmentioning

confidence: 99%

A SEI Modeling Approach Distinguishing between Capacity and Power Fade

Kindermann

Keil

Frank

et al. 2017

J. Electrochem. Soc.

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“…Another factor affecting SEI layer growth could be cracking of the SEI layer due to fiber expansion, this has been suggested and modeled with good fit for graphite particles. 21 Since the carbon fibers have been shown to expand during lithiation, 20 a similar effect could be the reason for the steeper slopes during the first few cycles in Figure 5. However, the slopes are linear after around 100 hours, suggesting time to be the dominant factor affecting SEI layer growth, and that cracking of the SEI layer is mainly a problem during the first few cycles.…”

mentioning

confidence: 93%

High Precision Coulometry of Commercial PAN-Based Carbon Fibers as Electrodes in Structural Batteries

Hagberg

Leijonmarck

Lindbergh

2016

J. Electrochem. Soc.

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Carbon fibers have the combined mechanical and electrochemical properties needed to make them particularly well suited for usage as electrodes in a structural lithium-ion battery, a material that simultaneously works as a battery and a structural composite. Presented in this paper is an evaluation of commercial polyacrylonitrile-based carbon fibers in terms of capacity and coulombic efficiency, as well as a microstructural and surface evaluation. Some polyacrylonitrile based carbon fibers intercalate lithium ions, resulting in a similar capacity as state-of-the-art graphite based electrodes, presently the most commonly used negative electrode material. Using high precision coulometry, we found a capacity of around 250-350 mAh/g and a very high coulombic efficiency of over 99.9% after ten cycles, which is even higher than a commercial state-of-the art graphitic electrode evaluated as reference. The high coulombic efficiency is attributed to the very low surface area of the carbon fibers, resulting in a small and stable solid-electrolyte interface layer. A highly graphitized ultra high modulus carbon fiber was evaluated as well and, compared to the other fibers, less lithium was inserted (corresponding to approximately 150 mAh/g). We show that the use of carbon fibers as an electrode material in a structural composite battery is indeed viable. The demand for new and improved battery technologies is continuously rising. In particular the electrification of the transportation sector needs innovative new solutions to develop and meet new demands. Much research is dedicated to pushing the limits of lithium (Li)-ion batteries in terms of energy, power, safety, cost, lifetime and environmental aspects.Improving graphite and other carbon based electrodes has been extensively researched since the beginning of the 90s since they are the dominating type of negative electrodes in Li-ion batteries.1-5 Another way of improving the effectiveness at a system level is through so called multifunctional battery technologies. The idea is to let the battery perform several functions, in particular carry a mechanical load and still maintain the energy storage function. The weight at a system level can be reduced, and a performance enhancement can be achieved, even if the battery function is not on par with conventional state of the art Li-ion batteries. Batteries could be included as an integral part of the structure in different kinds of vehicles, such as cars or even airplanes. Multifunctionality of materials for battery and capacitor applications has been researched in various ways for a number of years. [6][7][8][9][10][11][12][13]

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“…This shifts the capacity balancing of anode to cathode towards values >1 with respect to the reversible capacity. A capacity ratio of anode/cathode >1 allows a complete (de-)lithiation of the cathode and avoids safety-critical dendrite formation and lithium plating [18][19][20][21].…”

Section: Sample Ageing and Cell Preparationmentioning

confidence: 99%

Ageing and Water-Based Processing of LiFeMnPO4 Secondary Agglomerates and Its Effects on Electrochemical Characteristics

et al. 2017

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LiFeMnPO 4 secondary agglomerates have been aged under different temperature and moisture conditions. The aged and pristine powder samples were then processed to water-and solvent-based cathodes. Structural studies by means of neutron and X-ray diffraction revealed that neither ageing nor water-based processing significantly modified the crystal structure of LiFeMnPO 4 secondary agglomerates. Electrochemical characterization was carried out with full-cells. It was found that long-term cycling is similar independent of the solvent used for slurry preparation. Full-cells assembled with water-based cathodes show a better C-rate capability due to a more homogeneous distribution of cathode constituents compared to solvent-based ones. In no case was any negative effect of initial active material ageing on the electrochemical performance found. During ageing and processing, LiFeMnPO 4 is effectively protected by carbon coating and water can be completely removed by drying since it is only reversibly bound. This contribution shows that LiFeMnPO 4 secondary agglomerates allow simplified active material handling and have a high potential for sustainable water-based electrode manufacturing.

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A Model for Predicting Capacity Fade due to SEI Formation in a Commercial Graphite/LiFePO₄Cell

Cited by 141 publications

References 23 publications

A SEI Modeling Approach Distinguishing between Capacity and Power Fade

A SEI Modeling Approach Distinguishing between Capacity and Power Fade

High Precision Coulometry of Commercial PAN-Based Carbon Fibers as Electrodes in Structural Batteries

Ageing and Water-Based Processing of LiFeMnPO4 Secondary Agglomerates and Its Effects on Electrochemical Characteristics

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A Model for Predicting Capacity Fade due to SEI Formation in a Commercial Graphite/LiFePO4Cell

Cited by 141 publications

References 23 publications

A SEI Modeling Approach Distinguishing between Capacity and Power Fade

A SEI Modeling Approach Distinguishing between Capacity and Power Fade

High Precision Coulometry of Commercial PAN-Based Carbon Fibers as Electrodes in Structural Batteries

Ageing and Water-Based Processing of LiFeMnPO4 Secondary Agglomerates and Its Effects on Electrochemical Characteristics

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A Model for Predicting Capacity Fade due to SEI Formation in a Commercial Graphite/LiFePO₄Cell