Simple Method to Relate Experimental Pore Size Distribution and Discharge Capacity in Cathodes for Li/O<sub>2</sub> Batteries

Olivares-Marín, Mara; Palomino, Pablo; Enciso, E.; Tonti, Dino

doi:10.1021/jp5053453

Cited by 31 publications

(41 citation statements)

References 73 publications

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“…2a, the slurry-coated cathode is composed of the carbon black particles aggregated with Nafion binder, where the large pores are hardly seen. This is also consistent with the data reported elsewhere using the N 2 sorption isotherm, which proved that conventional carbon black electrodes mostly consist of micro-pores and lacks of macro-pores [18,38]. However, Fig.…”

Section: Morphology Of the As-deposited Cathodesupporting

confidence: 93%

Screen printed cathode for non-aqueous lithium–oxygen batteries

Jung

Zhao

et al. 2015

Journal of Power Sources

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Section: Morphology Of the As-deposited Cathodesupporting

confidence: 93%

Screen printed cathode for non-aqueous lithium–oxygen batteries

Jung

Zhao

et al. 2015

Journal of Power Sources

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“…11,37,38 We consider a composite cathode with an experimentally measured PSD in nanometer to micrometer range representative of the Super P carbon. The associated surface area distribution to this PSD is shown in Fig.…”

Section: Model Developmentmentioning

confidence: 99%

A Comprehensive Model for Non-Aqueous Lithium Air Batteries Involving Different Reaction Mechanisms

Xue

McTurk

Johnson

et al. 2015

J. Electrochem. Soc.

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There are various reaction mechanisms in the discharge process of a non-aqueous lithium air battery (LAB). Recently, it has been identified that low current rate and high donor number solvents can lead to solution phase reaction, but high current rate and low donor number solvents will cause thin film growth covering the active cathode surface. In this paper we extend our previous LAB multiscale model, which considers the thin film growth mode, to the general case where both surface thin film growth and solution phase reaction coexist. A detailed mechanism is proposed and simulation results are compared with experimental data.

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“…The pore size distribution measured by experiments usually follows a log normal distribution and the mean pore size varies from 10 to 120 nm. 23 In this study, electrodes with a series of pore size distributions are simulated, the mean pore size changes from 10 to 100 nm as shown in the inserted plot in Figure 5. The surface area per volume of these electrodes decreases from 0.21 to 0.03 nm 2 /nm 3 when the mean pore size increases from 10 to 100 nm considering the fact that the surface area to volume ratio of smaller pores is higher than that of larger pores.…”

Section: Resultsmentioning

confidence: 99%

A Modeling Study of the Pore Size Evolution in Lithium-Oxygen Battery Electrodes

2015

J. Electrochem. Soc.

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This study develops a statistics model that investigates the microstructural evolution of porous electrodes and couples the micro structural changes with a computational fluid dynamics model to simulate the discharge performance of an 800-μm-thick electrode at 1 A/m 2 . This study considers the fact that pores that are too small to hold reactants, smaller than a critical pore size, do not contribute to the discharge of the battery. It is found that when the pore size of the electrode increases, the discharge capacity of the electrode first increases due to the improved mass transfer and then decreases due to the decrease of the effective surface area. For instance, when the critical pore size is set as 10 nm, the discharge capacity gradually increases from 86.6 to 214.8 mAh/g carbon when the mean pore size of the electrode increases from 10 to 50 nm, followed by a capacity decrease to 150.8 mAh/g carbon when the mean pore size further increases to 100 nm. This study also finds that alternating the discharge current between 0 (open circuit condition) and the setting current rate can increase the discharge capacity of the lithium-oxygen battery because the oxygen concentration in the electrode increases during the open circuit condition. The increasing energy demands from portable electronic devices and the target of 300 miles driving range of electric vehicles have placed tremendous pressure on current electrical storage systems. Electric storage technologies with very high specific energy are required in order to meet the ever increasing energy demand without significantly increase the weight of the energy storage system. The lithium-oxygen battery is considered as a promising energy storage technology for portable and transportation applications considering its exceptionally high specific energy. Within four types of lithiumoxygen batteries, 1 the battery using organic electrolyte has attracted the most attention.2 Although the active intermediates may react with non-aqueous electrolytes and produce lithium carbonate, lithium hydroxide, and lithium alkyl carbonate, 3-6 the main product is expected to be Li 2 O 2 2 . The overall reaction happens during charge and discharge of a lithium-oxygen battery using organic electrolyte is:The theoretical energy density of the lithium-oxygen battery is calculated to be 11,680 Wh (kg lithium) −1 or 2,790 Wh (kg lithium and oxygen) −1 . 7 The measured specific energy of lithium-oxygen batteries reported in literature, however, is less than 10% of the theoretical specific energy. 8,9 The power, capacity and efficiency of batteries are restricted by the cathode gas diffusion electrode (GDE), which is typically made from carbon material, considering the high energy density of lithium metal and fast reaction rate of lithium electrode. 6,[10][11][12][13][14] In particular, the low solubility and diffusivity of oxygen in nonaqueous electrolytes limit the current density and the capacity of the battery.9,15-19 Meanwhile, pores with different sizes in the electrode have different im...

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Simple Method to Relate Experimental Pore Size Distribution and Discharge Capacity in Cathodes for Li/O₂ Batteries

Cited by 31 publications

References 73 publications

Screen printed cathode for non-aqueous lithium–oxygen batteries

Screen printed cathode for non-aqueous lithium–oxygen batteries

A Comprehensive Model for Non-Aqueous Lithium Air Batteries Involving Different Reaction Mechanisms

A Modeling Study of the Pore Size Evolution in Lithium-Oxygen Battery Electrodes

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Simple Method to Relate Experimental Pore Size Distribution and Discharge Capacity in Cathodes for Li/O2 Batteries

Cited by 31 publications

References 73 publications

Screen printed cathode for non-aqueous lithium–oxygen batteries

Screen printed cathode for non-aqueous lithium–oxygen batteries

A Comprehensive Model for Non-Aqueous Lithium Air Batteries Involving Different Reaction Mechanisms

A Modeling Study of the Pore Size Evolution in Lithium-Oxygen Battery Electrodes

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Product

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Simple Method to Relate Experimental Pore Size Distribution and Discharge Capacity in Cathodes for Li/O₂ Batteries