Optimizing Areal Capacities through Understanding the Limitations of Lithium-Ion Electrodes

Gallagher, Kevin G.; Trask, Stephen E.; Bauer, Christoph; Woehrle, Thomas; Lux, Simon Franz; Tschech, Matthias; Lamp, Peter; Polzin, Bryant J.; Ha, Seungbum; Long, Brandon R.; Wu, Qingliu; Lu, Wenquan; Dees, Dennis W.; Jansen, Andrew N.

doi:10.1149/2.0321602jes

Cited by 534 publications

(474 citation statements)

References 32 publications

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“…63,64 LiFePO 4 and NMC thick electrodes have been optimized by a combined experimental and simulation approach. 65,66 Efforts have been put forth in a variable porosity electrode, but this has only led to marginal improvements in energy density compared with well-designed constant-porosity electrodes, suggesting it is more important to decrease the tortuosity. 67 Numerical simulation has also been applied to investigate the limiting factors of the energy-power density relationship in LiNi 0.8 Co 0.15 Al 0.05 O 2 (NCA)/ graphite cells with thick electrodes.…”

Section: Electrode Engineeringmentioning

confidence: 99%

Toward Low-Cost, High-Energy Density, and High-Power Density Lithium-Ion Batteries

Ruther

et al. 2017

JOM

232

136

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Reducing cost and increasing energy density are two barriers for widespread application of lithium-ion batteries in electric vehicles. Although the cost of electric vehicle batteries has been reduced by $70% from 2008 to 2015, the current battery pack cost ($268/kWh in 2015) is still >2 times what the USABC targets ($125/kWh). Even though many advancements in cell chemistry have been realized since the lithium-ion battery was first commercialized in 1991, few major breakthroughs have occurred in the past decade. Therefore, future cost reduction will rely on cell manufacturing and broader market acceptance. This article discusses three major aspects for cost reduction: (1) quality control to minimize scrap rate in cell manufacturing; (2) novel electrode processing and engineering to reduce processing cost and increase energy density and throughputs; and (3) material development and optimization for lithium-ion batteries with high-energy density. Insights on increasing energy and power densities of lithium-ion batteries are also addressed.

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Section: Electrode Engineeringmentioning

confidence: 99%

Toward Low-Cost, High-Energy Density, and High-Power Density Lithium-Ion Batteries

Ruther

et al. 2017

JOM

232

136

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“…Thus, the accessible lithiation capacities at high C-rate (1 1/h) differ strongly amongst these electrodes, although their porosity, thickness, and areal capacities are comparable (see Table II), clearly showing the significant effect of electrode tortuosity on the charging potential vs. SOC behavior, as would be expected based on theoretical models. 20,21 In addition to the difference in lithiation capacities at 1 1/h, Figure 4b also illustrates two other distinctive features in the lithiation potential vs. SOC profiles for increasing tortuosities, namely an increasing overpotential and a smearing out or complete loss of the typical potential steps in the graphite lithiation process at high C-rates. At the slow charging rate of 0.1 1/h, the graphite lithiation plateaus (around SOC values of 10%, 20%, and 55%) are clearly distinguishable and similarly well-defined for all graphite electrodes despite their vastly different tortuosities (compare Figure 4a).…”

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confidence: 90%

“…14 in Ref. 20). Applied to our measurements this would mean that the product of the critical C-rate R crit.…”

mentioning

confidence: 99%

“…To verify the expected behavior of better performance for low tortuosity electrodes, 20,21 we picked three electrode compositions with different tortuosities but similar areal capacity, thickness, and porosity in order to compare their electrochemical performance and their rate capability using three-electrode cells with a lithium counter and a lithium reference electrode. As the limiting operation mode for graphite anodes is the charging step, due to the proximity of the graphite intercalation potential to the lithium plating potential, we focus our analysis on the charging (i.e., lithiation) behavior of graphite anodes.…”

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Influence of the Binder on Lithium Ion Battery Electrode Tortuosity and Performance

Landesfeind

Eldiven

Gasteiger

2018

J. Electrochem. Soc.

114

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The electrochemical performance of porous graphite anodes in lithium ion battery applications is limited by the lithium ion concentration gradients in the liquid electrolyte, especially at high current densities and for thick coatings during battery charging. Beside the electrolyte transport parameters, the porosity and the tortuosity of the coating are key parameters that determine the electrode's suitability for high power applications. Here, we investigate the tortuosity of graphite anodes using two water as well as three n-methyl-2-pyrrolidone based binder systems by analysis of symmetric cell impedance measurements, demonstrating that tortuosities ranging from ∼3-10 are obtained for graphite anodes of similar thickness (∼100 μm), porosities (∼50%) and areal capacity (∼3.4 mAh/cm 2 ). Furthermore, selected electrodes with tortuosities of 3.1, 4.3, and 10.2 were cycled in cells with reference electrode at charging C-rates from 0. Understanding and predicting rate limitations in lithium ion batteries with porous electrodes requires profound knowledge of not only the electrolyte transport parameters (i.e., transference number, diffusion coefficient, conductivity) and the thermodynamic factor, but also the porosity and the tortuosity of the electrodes. The tortuosity of the electrode is particularly critical because the effective electrolyte conductivity and the effective diffusion coefficient in the electrolyte directly scale with the inverse of the tortuosity, so that care has to be taken to develop electrodes with minimized tortuosity. Using experimental approaches 1-4 or 3D tomography, 5,6 it was shown that the shape of active material particles distinctly influences the electrode tortuosity. For a given active material, however, electrode tortuosity and rate capability can also be improved by the design of the electrode layer such that short diffusion distances can be obtained across the electrode. For example, improved performance was demonstrated for graphite anodes when the platelet graphite particles were aligned normal to the current collector surface by means of a magnetic field 7 or when silicon/graphite anode electrodes were laser structured. 8 In this study we focus on the role of the electrode composition, specifically the role of the binder, on its tortuosity as well as on its implication for battery performance. While in the literature the link between binder and electrochemistry is frequently studied empirically using rate capability tests 9 and long-term cycling experiments, 10-13 we focus on the correlation of electrode tortuosity with binder content/type and its effect on rate capability.In the following, the tortuosity of graphite anodes with different binders, different binder contents, and different amounts of conductive carbon additive will be determined by electrochemical impedance spectroscopy (EIS) of symmetric cells using the transmission line model approach. 3,14 In the first part of our analysis we will demonstrate the effect of binder and conductive carbon additives on electrode t...

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“…This clearly demonstrates the limitation of the C-rate with increasing nanoarray height. The reason for this limitation can be found in the uneven distribution of current density in the nanoarray, which is due to limited Li + -ion diffusivity within the nanoarray [58,59]. On discharging, the current density is shifted from the separator/electrode boundary towards the current collector.…”

Section: Structure Property Relationship In Lto-vacnt Nanoarraysmentioning

confidence: 99%

Nanostructured Networks for Energy Storage: Vertically Aligned Carbon Nanotubes (VACNT) as Current Collectors for High-Power Li4Ti5O12(LTO)//LiMn2O4(LMO) Lithium-Ion Batteries

et al. 2017

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Abstract:As a concept for electrode architecture in high power lithium ion batteries, self-supported nanoarrays enable ultra-high power densities as a result of their open pore geometry, which results in short and direct Li + -ion and electron pathways. Vertically aligned carbon nanotubes (VACNT) on metallic current collectors with low interface resistance are used as current collectors for the chemical solution infiltration of electroactive oxides to produce vertically aligned carbon nanotubes decorated with in situ grown LiMn 2 O 4 (LMO) and Li 4 Ti 5 O 12 (LTO) nanoparticles. The production processes steps (catalyst coating, VACNT chemical vapor deposition (CVD), infiltration, and thermal transformation) are all scalable, continuous, and suitable for niche market production to achieve high oxide loadings up to 70 wt %. Due to their unique transport structure, as-prepared nanoarrays achieve remarkably high power densities up to 2.58 kW kg −1 , which is based on the total electrode mass at 80 C for LiMn 2 O 4 //Li 4 Ti 5 O 12 full cells. The tailoring of LTO and LMO nanoparticle size (~20-100 nm) and VACNT length (array height: 60-200 µm) gives insights into the rate-limiting steps at high current for these kinds of nanoarray electrodes at very high C-rates of up to 200 C. The results reveal the critical structural parameters for achieving high power densities in VACNT nanoarray full cells.

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Optimizing Areal Capacities through Understanding the Limitations of Lithium-Ion Electrodes

Cited by 534 publications

References 32 publications

Toward Low-Cost, High-Energy Density, and High-Power Density Lithium-Ion Batteries

Toward Low-Cost, High-Energy Density, and High-Power Density Lithium-Ion Batteries

Influence of the Binder on Lithium Ion Battery Electrode Tortuosity and Performance

Nanostructured Networks for Energy Storage: Vertically Aligned Carbon Nanotubes (VACNT) as Current Collectors for High-Power Li4Ti5O12(LTO)//LiMn2O4(LMO) Lithium-Ion Batteries

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