On Graded Electrode Porosity as a Design Tool for Improving the Energy Density of Batteries

Dai, Yiling; Srinivasan, Venkat

doi:10.1149/2.0301603jes

Cited by 87 publications

(85 citation statements)

References 40 publications

(129 reference statements)

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“…However, the average porosities for 2-layer, 3-layer, 4-layer, and 5-layer graded electrode were 0.3214, 0.3152, 0.3135, and 0.3119 respectively, not far from the uniform optimal porosity 0.3435. With the same active material constraint, the minimal resistances for 2-layer, 3-layer, 4-layer, and 5-layer graded electrode are 5.1300 -cm 2 , 5.0976 -cm 2 , 5.0823 -cm 2 , and 5.0748 -cm 2 , which are slightly larger than the values in Table III. If a conclusion was to be made just based on the results so far, it would confirm the conclusion from Dai et al 13 that graded porosity is not very useful. However, the next section will show the cases where graded design in the electrode is needed.…”

Section: Resultssupporting

confidence: 58%

“…Recently, Dai et al 13 carefully looked at the performance improvement by utilizing a full P2D model and recommended the manufacturers not to make the graded electrode due to the additional processes involved and very small improvement achieved. In this paper, we want to quantify the gain in terms of electrode resistance with the two optimization approaches.…”

Section: Resultsmentioning

confidence: 99%

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Is There a Benefit in Employing Graded Electrodes for Lithium-Ion Batteries?

Jang

Ramadesigan

et al. 2017

J. Electrochem. Soc.

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Literature reports show both benefits and negligible impact when including graded electrodes in battery design, depending upon the exact model and conditions used. In this paper, we use two different optimization approaches for a secondary current distribution porous electrode model with nonlinear kinetics to confirm that computed solutions are correct. We use these confirmed optimal solutions to probe several ways that graded porosity can improve electrode performance. Single objective optimization such as reducing the overall electrode resistance using a graded electrode design provides a modest 4-6% reduction in resistance for typical lithium-ion battery parameters. Multiple objective optimization-for example, simultaneously considering electrode resistance and the overpotential variance and eventually the overpotential average as well-shows that multilayer designs open up a much richer feasible design space for achieving multiple goals. The ultimate answer to the value of graded electrodes will be the techno-economic analysis that links the benefits of an expanded optimal design space to the detrimental costs associated with manufacturing multilayer electrodes. An open-access executable code that can give optimal porosity distribution of any specified chemistry and detailed explanation of the two approaches can be found on the Subramanian group's website. Modeling and mathematical optimization can significantly improve the efficiency of battery design, helping to meet the growing demands for various applications. The idea of using modeling for battery design was first introduced by Tiedemann and Newman in 1975. 1 They used an ohmically limited porous electrode model to maximize the cell's effective capacity by changing the electrode thickness and porosity. Newman later applied the reaction-zone model to maximize the specific energy of the system, taking mass into consideration as well.2 For these two models, the objective function can be directly related to the design variables, thus the optimum can be obtained by simply observing the plot or from the analytical solution. They further optimized the thickness and porosity of a lithium iron phosphate 3 electrode, where they maximized the specific energy using the Ragone plots. Ramadesigan et al.4 went one step further by including the linear electrode kinetics to minimize the internal resistance of the electrode. They used control vector parameterization (CVP) to minimize the ohmic resistance in the positive electrode by varying porosity.With the development of battery modeling, more physical processes have been included, and one of the most popular physics based models is the pseudo-2-Dimensional (P2D) model developed by the Newman group. 5 The P2D model involves a set of nonlinear partial differential equations (PDEs) that can only be solved numerically. Therefore, a numerical optimization approach is required to perform optimization on the system. Du et al. proposed a surrogate-modelbased approach, 6 and later developed a sophisticated framework based on th...

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Section: Resultssupporting

confidence: 58%

Section: Resultsmentioning

confidence: 99%

Is There a Benefit in Employing Graded Electrodes for Lithium-Ion Batteries?

Jang

Ramadesigan

et al. 2017

J. Electrochem. Soc.

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“…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. 68 Lithium ion depletion in the electrolyte and lithium diffusion gradient in active material particles were found to attenuate the advantage of thick electrodes.…”

Section: Electrode Engineeringmentioning

confidence: 99%

“…Nevertheless, the Li-ion transport limitations in liquid electrolytes become increasingly important as the electrode thickness increases 67,68,70,71 because the diffusion time in the liquid phase is no longer negligible as a result of the significant increase in diffusion length in the thick porous electrodes. Consequently, it is necessary to design thick electrode architectures to take advantage of the increased energy density provided by the higher active material volume ratio, while minimizing the tortuosity and transport limitations that can be detrimental to power performance.…”

Section: Electrode Engineeringmentioning

confidence: 99%

“…Consequently, it is necessary to design thick electrode architectures to take advantage of the increased energy density provided by the higher active material volume ratio, while minimizing the tortuosity and transport limitations that can be detrimental to power performance. Many different designs have been suggested, including graded-porosity and hierarchical architectures, 67,[72][73][74][75][76] and several simulations have shown that smaller active material particles can help decrease the polarization and capacity loss observed at high discharge rates by shortening the Li-ion diffusion path in the particles. 68,71,77 Yet, particle size variations also affect the packing structure of the electrode and can result in different pore sizes and distributions, as well as in differences in the contact resistance between the electrode and the current collector.…”

Section: Electrode Engineeringmentioning

confidence: 99%

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

Ruther

et al. 2017

JOM

208

131

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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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3D Architected Carbon Electrodes for Energy Storage

Narita

Citrin

Yang

et al. 2020

Advanced Energy Materials

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The ability to design a particular geometry of porous electrodes at multiple length scales in a lithium‐ion battery can significantly and positively influence battery performance because it enables control over distribution of current and potential and can enhance ion and electron transport. 3D architecturally designed carbon electrodes are developed, whose structural factors are independently controlled and whose dimensions span micrometers to centimeters, using digital light processing and pyrolysis. These free‐standing lattice electrodes are comprised of monolithic glassy carbon beams, are lightweight, with a relative density of 0.1–0.35, and mechanically robust, with a maximum precollapse stress of 27 MPa, which facilitates electrode recycling. The specific strength is 101 kN m kg−1, comparable to that of 6061 aluminum alloy. These carbon electrodes can reach a mass loading of 70 mg cm−2 and an areal capacity of 3.2 mAh cm−2 at a current density of 2.4 mA cm−2. It is demonstrated that this approach allows for independent design of structural factors, i.e., beam diameter, electrode thickness, and surface morphology, enabling control over Li‐ion transport length, overpotential and battery performance, not available for slurry‐based electrodes. This multiscale approach to design of electrodes may open substantial performance‐enhancing capabilities for solid‐ and liquid‐state batteries, flow batteries, and fuel cells.

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On Graded Electrode Porosity as a Design Tool for Improving the Energy Density of Batteries

Cited by 87 publications

References 40 publications

Is There a Benefit in Employing Graded Electrodes for Lithium-Ion Batteries?

Is There a Benefit in Employing Graded Electrodes for Lithium-Ion Batteries?

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

3D Architected Carbon Electrodes for Energy Storage

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