Direct Evidence of Solution-Mediated Superoxide Transport and Organic Radical Formation in Sodium-Oxygen Batteries

Xia, Chun; Fernandes, Russel; Cho, Franklin H.; Sudhakar, Niranjan; Buonacorsi, Brandon; Walker, Sean B.; Xu, Meng; Baugh, Jonathan; Nazar, Linda F.

doi:10.1021/jacs.6b05382

Cited by 95 publications

(81 citation statements)

References 57 publications

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“…This is consistent with the cycling behavior of Na-O 2 batteries in Figure 4, as the Coulombic efficiency is slightly less than 100%. [38,39] In summary, hierarchical porous oxygen electrodes made of PCSs were synthesized and used as cathode material to realize an aprotic Na-O 2 battery with high capacity, high rate capability, and long cycle life. [37] In an attempt to completely decompose NaO 2 , the electrode potential was hold at 3.0 V for prolonged time (typically 10 min) after the charging voltage increased to the anodic cutoff potential, and a complete disappearance of the XRD pattern of NaO 2 was observed, as shown in Figure 5e.…”

Section: Figure 2 Ab) CV Curves (A) and Charge/discharge Voltage Prmentioning

confidence: 99%

Hierarchical Porous Carbon Spheres for High‐Performance Na–O₂ Batteries

et al. 2017

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As a new family member of room-temperature aprotic metal-O batteries, Na-O batteries, are attracting growing attention because of their relatively high theoretical specific energy and particularly their uncompromised round-trip efficiency. Here, a hierarchical porous carbon sphere (PCS) electrode that has outstanding properties to realize Na-O batteries with excellent electrochemical performances is reported. The controlled porosity of the PCS electrode, with macropores formed between PCSs and nanopores inside each PCS, enables effective formation/decomposition of NaO by facilitating the electrolyte impregnation and oxygen diffusion to the inner part of the oxygen electrode. In addition, the discharge product of NaO is deposited on the surface of individual PCSs with an unusual conformal film-like morphology, which can be more easily decomposed than the commonly observed microsized NaO cubes in Na-O batteries. A combination of coulometry, X-ray diffraction, and in situ differential electrochemical mass spectrometry provides compelling evidence that the operation of the PCS-based Na-O battery is underpinned by the formation and decomposition of NaO . This work demonstrates that employing nanostructured carbon materials to control the porosity, pore-size distribution of the oxygen electrodes, and the morphology of the discharged NaO is a promising strategy to develop high-performance Na-O batteries.

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Section: Figure 2 Ab) CV Curves (A) and Charge/discharge Voltage Prmentioning

confidence: 99%

Hierarchical Porous Carbon Spheres for High‐Performance Na–O₂ Batteries

et al. 2017

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“…This idea is also supported by experimental measurements of other superoxide phases such as potassium, rubidium, and cesium . One explanation for the low overpotentials observed with NaO 2 could be solution‐meditated growth . Xia et al.…”

Section: Sodium‐oxygen Batteriesmentioning

confidence: 99%

“…[23] One explanation for the low overpotentials observed with NaO 2 could be solution-meditated growth. [24][25][26] Xia et al studied the influence of water content in the electrolyte. [27] Dry electrolytes exhibited very low capacities compared with electrolytes with 10 ppm of water.R otating ring disc electrode (RRDE)m easurements also confirm an increase in the soluble superoxide species.…”

Section: Discharge Productmentioning

confidence: 99%

Alkali‐Oxygen Batteries Based on Reversible Superoxide Chemistry

McCulloch

Xiao

Gourdin

et al. 2018

Chemistry A European J

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Rechargeable superoxide (O ) batteries have the potential to surpass current lithium-ion technology due to their high theoretical energy densities. The use of superoxides as an energy storage material is highly advantageous when compared to their close relatives, peroxides. This is due to enhanced reversibility of the 1-electron redox process. To efficiently stabilize superoxides, larger metal cations are required such as sodium and potassium. Therefore, the two most studied systems are sodium and potassium-oxygen batteries. Both batteries present unique advantages and challenges. In this minireview, we summarize the current research for each superoxide-based battery and offer perspective for further research.

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“…During the typical electrochemical process of Na–air battery, the sodium metal is oxidized and sodium ions migrate across the organic/organic–aqueous electrolyte. After oxygen dissolving in the regions of electrolyte near cathode, superoxide species (O 2 − ) are generated, where sodium superoxide is then formed as the discharge product . The schematic diagram of a typical Na–air battery is shown in Figure A.…”

Section: Sodium–air Batteriesmentioning

confidence: 99%

Electrocatalysis of Rechargeable Non‐Lithium Metal–Air Batteries

Zhao

et al. 2017

Adv Materials Inter

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As the critical component for rechargeable metal-air batteries, bifunctional catalysts for both oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) are under the intensive investigation for different systems. [1] Noble metals and their alloys are first introduced for metal-air batteries, especially for the good ORR performance of Pt. Later, nonprecious metal oxides and their composites are applied for their low price and comparable good catalytic performance. [21][22][23][24] Lately, various 3D structured and metalfree carbon catalysts are developed for their large specific surface area, good corrosion resistance, high stability, and low price. [25][26][27][28] In general, nanocrystals and complex nanostructures represent a world of new possibilities and exciting opportunities. Their morphologies and composition are highly tunable and controllable, which can expose different facets and cause different atomic arrangements on the surface, leading to the enhanced ORR and/or OER performance. Meanwhile, soluble catalysts are also very important in Li-/Na-air battery systems. So far, ethyl viologen redox couple, halide anions, aromatic compounds, quiones/quinoids, and transition metal complexes have been successfully applied in metal-air systems, where the battery shows much improved battery cyclic life and smaller overpotential. [29,30] In respect of the rapid growth of investigations, we summarize the recent progress of secondary non-lithium metal-air batteries, discuss the important issues of electrochemical reactions and bifunctional catalysts. Future perspectives are offered in the end, which should shed light on further research and design of bifunctional catalysts for secondary metal-air batteries. This mini review is organized in the following sequence: Na-air battery, Zn-air battery, and others like K-/Mg-air batteries. Sodium-Air BatteriesRecently, the substitution of lithium by sodium has been a promising solution to surpass Li-air limitations of high price, lower Coulombic efficiency, and large overpotential. [31][32][33][34] During the typical electrochemical process of Na-air battery, the sodium metal is oxidized and sodium ions migrate across the organic/ organic-aqueous electrolyte. After oxygen dissolving in the regions of electrolyte near cathode, superoxide species (O 2 − ) are generated, where sodium superoxide is then formed as the discharge product. [35][36][37][38][39][40][41][42] The schematic diagram of a typical Na-air Rechargeable metal-air batteries show great promise in replacing conventional batteries due to their high theoretical energy density and infinite oxygen fuel from air. Rechargeable non-Li-air batteries display the benefits of low price, high Coulombic efficiency, and small overpotential. Whereas in the case of Li-air batteries, the occurring electrocatalysis is intensively investigated, the situation is much less studied in the case of non-lithium metal-air batteries. In this progress report, recent developments of secondary non-lithium metal-air batteries are su...

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Direct Evidence of Solution-Mediated Superoxide Transport and Organic Radical Formation in Sodium-Oxygen Batteries

Cited by 95 publications

References 57 publications

Hierarchical Porous Carbon Spheres for High‐Performance Na–O₂ Batteries

Hierarchical Porous Carbon Spheres for High‐Performance Na–O₂ Batteries

Alkali‐Oxygen Batteries Based on Reversible Superoxide Chemistry

Electrocatalysis of Rechargeable Non‐Lithium Metal–Air Batteries

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Direct Evidence of Solution-Mediated Superoxide Transport and Organic Radical Formation in Sodium-Oxygen Batteries

Cited by 95 publications

References 57 publications

Hierarchical Porous Carbon Spheres for High‐Performance Na–O2 Batteries

Hierarchical Porous Carbon Spheres for High‐Performance Na–O2 Batteries

Alkali‐Oxygen Batteries Based on Reversible Superoxide Chemistry

Electrocatalysis of Rechargeable Non‐Lithium Metal–Air Batteries

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Hierarchical Porous Carbon Spheres for High‐Performance Na–O₂ Batteries

Hierarchical Porous Carbon Spheres for High‐Performance Na–O₂ Batteries