Trade-Offs in Capacity and Rechargeability in Nonaqueous Li–O<sub>2</sub> Batteries: Solution-Driven Growth versus Nucleophilic Stability

Khetan, Abhishek; Luntz, A. C.; Viswanathan, Venkatasubramanian

doi:10.1021/acs.jpclett.5b00324

Cited by 135 publications

(167 citation statements)

References 36 publications

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“…However, there is tremendous scope in tuning the electrolyte anion in low-DN solvents to obtain high discharge capacities. Given that it should be simpler to identify anions stable to the Li-O 2 cathode electrochemistry than high-DN solvents (36,37), anion selection in combination with low-DN solvents potentially provides a route to avoid the unfavorable capacity/stability trade-off observed in high-DN solvents, such as DMSO (14,15,38,39).…”

Section: Resultsmentioning

confidence: 99%

“…Furthermore, using quantitative measures of battery rechargeability, high-DN solvents, such as DMSO and N-methyl pyrrolidone, have been observed to be less stable than low-DN solvents, such as acetonitrile and DME (14). Recently, Khetan et al used a thermodynamic analysis to show that an organic solvent's ability to induce the solution mechanism is anticorrelated with its stability toward nucleophilic attack (15 (16,17). We found that electrolytes containing a high concentration of NO 3 − exhibited higher donicity, as verified using 7 Li NMR, and provided an increase in battery capacity greater than fourfold compared with a battery using exclusively TFSI − as the electrolyte anion, while not decreasing battery rechargeability, as measured using quantitative oxygen consumption and evolution.…”

Section: Significancementioning

confidence: 99%

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Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li–O ₂ battery capacity

Burke

Pande

Khetan

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Among the "beyond Li-ion" battery chemistries, nonaqueous Li-O 2 batteries have the highest theoretical specific energy and, as a result, have attracted significant research attention over the past decade. A critical scientific challenge facing nonaqueous Li-O 2 batteries is the electronically insulating nature of the primary discharge product, lithium peroxide, which passivates the battery cathode as it is formed, leading to low ultimate cell capacities. Recently, strategies to enhance solubility to circumvent this issue have been reported, but rely upon electrolyte formulations that further decrease the overall electrochemical stability of the system, thereby deleteriously affecting battery rechargeability. In this study, we report that a significant enhancement (greater than fourfold) in Li-O 2 cell capacity is possible by appropriately selecting the salt anion in the electrolyte solution. Using 7 Li NMR and modeling, we confirm that this improvement is a result of enhanced Li + stability in solution, which, in turn, induces solubility of the intermediate to Li 2 O 2 formation. Using this strategy, the challenging task of identifying an electrolyte solvent that possesses the anticorrelated properties of high intermediate solubility and solvent stability is alleviated, potentially providing a pathway to develop an electrolyte that affords both high capacity and rechargeability. We believe the model and strategy presented here will be generally useful to enhance Coulombic efficiency in many electrochemical systems (e.g., Li-S batteries) where improving intermediate stability in solution could induce desired mechanisms of product formation.donor number | solubility | lithium nitrate | NMR | Li-air battery T he lithium-oxygen (Li-O 2 ) battery has garnered significant research interest in the past 10 y due to its high theoretical specific energy compared with current state-of-the-art lithiumion (Li-ion) batteries (1, 2). Consisting of a lithium anode and an oxygen cathode, the nonaqueous Li-O 2 battery operates via the electrochemical formation and decomposition of lithium peroxide (Li 2 O 2 ). The ideal overall reversible cell reaction is thereforeOne challenge preventing the realization of a modest fraction of the Li-O 2 battery's high theoretical specific energy is that the discharge product, Li 2 O 2 , which is generally insoluble in aprotic organic electrolytes, is an insulator (3-5). As Li 2 O 2 is conformally deposited on the cathode's carbon support during discharge, it electronically passivates the cathode, resulting in practical capacities much smaller than theoretically attainable (6). Recently, two reports described the engineering of electrolytes to circumvent this passivation and improve Li-O 2 battery discharge capacity. Aetukuri et al. suggested that adding ppm quantities of water to a 1,2-dimethoxyethane (DME)-based electrolyte increases the solubility of intermediates during Li 2 O 2 formation (7). This increased solubility allows a reduced oxygen species shuttling mechanism that promotes deposi...

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Section: Resultsmentioning

confidence: 99%

Section: Significancementioning

confidence: 99%

Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li–O ₂ battery capacity

Burke

Pande

Khetan

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

320

344

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“…[50] As Li + solvation structures can vary greatly among similar solvents (for example, glymes), [51,52] and across different classes of solvents such as ionic liquids, [53] À potentials. These results highlight the importance of the interplay between ion-solvent and ion-ion interactions in understanding and controlling the intermediate species energetics, reaction product morphology, discharge capacity, and solvent stability in aprotic metal-O 2 batteries.…”

mentioning

confidence: 99%

Experimental and Computational Analysis of the Solvent‐Dependent O₂/Li⁺‐O₂⁻ Redox Couple: Standard Potentials, Coupling Strength, and Implications for Lithium–Oxygen Batteries

et al. 2016

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“…27 Ideally, future electrolyte solvents should possess high AN or DN to facilitate toroid formation and maximize discharge capacity without exacerbating by-product formation. 28,29 The search for more stable electrolyte and cathode pairings for Li-O 2 batteries has become a critical area of research and will likely determine the long term prospects of the Li-O 2 system. 30,31 To date, the pursuit of sufficiently stable electrolytes (i.e.…”

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confidence: 99%

Examining the Role of Electrolyte and Binders in Determining Discharge Product Morphology and Cycling Performance of Carbon Cathodes in Li-O₂Batteries

Geaney

O’Dwyer

2015

J. Electrochem. Soc.

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In this report we examine the influence of electrode binder and electrolyte solvent on the electrochemical response of carbon based Li-O 2 battery cathodes. Much higher discharge capacities were noted for cathodes discharged in DMSO compared to TEGDME. The increased capacities were related to the large spherical discharge products formed in DMSO. Characteristic toroids which have been noted in TEGDME electrolytes previously were not observed due to the low water content of the electrolyte. Linear voltage sweeps were used to investigate ORR in both of the solvents for each of the binder systems (PVDF, PVP, PEO and PTFE) and related to the Li 2 O 2 formed on the cathode surfaces. Galvanostatic tests were also conducted in air as a comparison with the pure O 2 environment typically used for Li-O 2 battery testing. Interestingly, tests for the two electrolytes showed opposite trends in terms of discharge capacity values with capacities increased in TEGDME (compared to those seen in O 2 ) and decreased in DMSO. The report highlights the key roles of electrolyte and cathode composition in determining the stability of Li-O 2 batteries and highlights the importance of identifying more stable electrolyte/cathode pairings. Li-O 2 batteries are an exciting class of energy storage devices with exceptional theoretical capacities which could facilitate longrange electrical vehicles if fully optimized systems are realized. [1][2][3][4][5] Energy storage in Li-O 2 batteries proceeds via different mechanisms to those associated with conventional Li-ion batteries, necessitating detailed studies into the fundamental processes associated with discharge and charge.6-8 It has been shown in a number of studies that the energy storage mechanism for Li-O 2 batteries involves the reversible formation/decomposition of Li 2 O 2 upon discharge and charge respectively.9-13 While the O 2 required to form Li 2 O 2 during discharge can theoretically be provided from ambient air, the majority of systems investigated to date have used pure O 2 to avoid unwanted side-reactions due to the ingress of atmospheric CO 2 and H 2 O.14,15 The formation of parasitic by-products in Li-O 2 batteries (which have been found to form extensively on charging due to cathode and electrolyte instabilities) is a major hurdle to their widespread implementation. 16,17 The nature of Li 2 O 2 (i.e morphology, crystallinity, size and location on the cathode) formed during discharge, and its impact on capacity, cycle life and charging behavior has attracted recent research interest.18-20 A number of reports have presented the formation of Li 2 O 2 toroids on cathode surfaces during discharge in a variety of cathode/electrolyte systems. 7,8,12,19,[21][22][23][24][25] Adams et al. showed that the formation of these toroids was related to the applied current for a given system (TEGDME/LiTFSI electrolyte and Super P carbon cathode). 26Their results suggested that low applied currents tend to favor the formation of large crystalline Li 2 O 2 toroids on the cathode surface with ...

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Trade-Offs in Capacity and Rechargeability in Nonaqueous Li–O₂ Batteries: Solution-Driven Growth versus Nucleophilic Stability

Cited by 135 publications

References 36 publications

Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li–O ₂ battery capacity

Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li–O ₂ battery capacity

Experimental and Computational Analysis of the Solvent‐Dependent O₂/Li⁺‐O₂⁻ Redox Couple: Standard Potentials, Coupling Strength, and Implications for Lithium–Oxygen Batteries

Examining the Role of Electrolyte and Binders in Determining Discharge Product Morphology and Cycling Performance of Carbon Cathodes in Li-O₂Batteries

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Trade-Offs in Capacity and Rechargeability in Nonaqueous Li–O2 Batteries: Solution-Driven Growth versus Nucleophilic Stability

Cited by 135 publications

References 36 publications

Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li–O 2 battery capacity

Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li–O 2 battery capacity

Experimental and Computational Analysis of the Solvent‐Dependent O2/Li+‐O2− Redox Couple: Standard Potentials, Coupling Strength, and Implications for Lithium–Oxygen Batteries

Examining the Role of Electrolyte and Binders in Determining Discharge Product Morphology and Cycling Performance of Carbon Cathodes in Li-O2Batteries

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Trade-Offs in Capacity and Rechargeability in Nonaqueous Li–O₂ Batteries: Solution-Driven Growth versus Nucleophilic Stability

Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li–O ₂ battery capacity

Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li–O ₂ battery capacity

Experimental and Computational Analysis of the Solvent‐Dependent O₂/Li⁺‐O₂⁻ Redox Couple: Standard Potentials, Coupling Strength, and Implications for Lithium–Oxygen Batteries

Examining the Role of Electrolyte and Binders in Determining Discharge Product Morphology and Cycling Performance of Carbon Cathodes in Li-O₂Batteries