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Literature DB >> 26706312

Combining Accurate O2 and Li2O2 Assays to Separate Discharge and Charge Stability Limitations in Nonaqueous Li-O2 Batteries.

Bryan D McCloskey¹, Alexia Valery^1,2, Alan C Luntz^1,3, Sanketh R Gowda¹, Gregory M Wallraff¹, Jeannette M Garcia¹, Takashi Mori^1,4, Leslie E Krupp¹.

Abstract

Li-air batteries have generated enormous interest as potential high specific energy alternatives to existing energy storage devices. However, Li-air batteries suffer from poor rechargeability caused by the instability of organic electrolytes and carbon cathodes. To understand and address this poor rechargeability, it is essential to elucidate the efficiency in which O2 is converted to Li2O2 (the desired discharge product) during discharge and the efficiency in which Li2O2 is oxidized back to O2 during charge. In this Letter, we combine many quantitative techniques, including a newly developed peroxide titration, to assign and quantify decomposition pathways occurring in cells employing a variety of solvents and cathodes. We find that Li2O2-induced electrolyte solvent and salt instabilities account for nearly all efficiency losses upon discharge, whereas both cathode and electrolyte instabilities are observed upon charge at high potentials.

Entities: Chemical

Keywords: Li−air battery; cathode; decomposition; electrolyte; peroxide; titration

Year: 2013 PMID： 26706312 DOI： 10.1021/jz401659f

Source DB: PubMed Journal: J Phys Chem Lett ISSN： 1948-7185 Impact factor: 6.475

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Cited

23 in total

1. Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li-O2 battery capacity.

Authors: Colin M Burke; Vikram Pande; Abhishek Khetan; Venkatasubramanian Viswanathan; Bryan D McCloskey
Journal: Proc Natl Acad Sci U S A Date: 2015-07-13 Impact factor: 11.205

Review 2. From lithium to sodium: cell chemistry of room temperature sodium-air and sodium-sulfur batteries.

Authors: Philipp Adelhelm; Pascal Hartmann; Conrad L Bender; Martin Busche; Christine Eufinger; Juergen Janek
Journal: Beilstein J Nanotechnol Date: 2015-04-23 Impact factor: 3.649

3. Solvating additives drive solution-mediated electrochemistry and enhance toroid growth in non-aqueous Li-O₂ batteries.

Authors: Nagaphani B Aetukuri; Bryan D McCloskey; Jeannette M García; Leslie E Krupp; Venkatasubramanian Viswanathan; Alan C Luntz
Journal: Nat Chem Date: 2014-12-15 Impact factor: 24.427

Combining Accurate O2 and Li2O2 Assays to Separate Discharge and Charge Stability Limitations in Nonaqueous Li-O2 Batteries.

1. Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li-O2 battery capacity.

Review 2. From lithium to sodium: cell chemistry of room temperature sodium-air and sodium-sulfur batteries.

3. Solvating additives drive solution-mediated electrochemistry and enhance toroid growth in non-aqueous Li-O₂ batteries.

Review 4. Advances in Lithium-Oxygen Batteries Based on Lithium Hydroxide Formation and Decomposition.

Review 5. Carbon Tube-Based Cathode for Li-CO₂ Batteries: A Review.

6. Promoting solution phase discharge in Li-O2 batteries containing weakly solvating electrolyte solutions.

7. Material balance in the O₂ electrode of Li-O₂ cells with a porous carbon electrode and TEGDME-based electrolytes.

8. A Highly Active Low Voltage Redox Mediator for Enhanced Rechargeability of Lithium-Oxygen Batteries.

Review 9. Why Do Lithium-Oxygen Batteries Fail: Parasitic Chemical Reactions and Their Synergistic Effect.

10. Mechanism and performance of lithium-oxygen batteries - a perspective.

Combining Accurate O2 and Li2O2 Assays to Separate Discharge and Charge Stability Limitations in Nonaqueous Li-O2 Batteries.

1. Enhancing electrochemical intermediate solvation through electrolyte anion selection to increase nonaqueous Li-O2 battery capacity.

Review 2. From lithium to sodium: cell chemistry of room temperature sodium-air and sodium-sulfur batteries.

3. Solvating additives drive solution-mediated electrochemistry and enhance toroid growth in non-aqueous Li-O₂ batteries.

Review 4. Advances in Lithium-Oxygen Batteries Based on Lithium Hydroxide Formation and Decomposition.

Review 5. Carbon Tube-Based Cathode for Li-CO2 Batteries: A Review.

6. Promoting solution phase discharge in Li-O2 batteries containing weakly solvating electrolyte solutions.

7. Material balance in the O2 electrode of Li-O2 cells with a porous carbon electrode and TEGDME-based electrolytes.

8. A Highly Active Low Voltage Redox Mediator for Enhanced Rechargeability of Lithium-Oxygen Batteries.

Review 9. Why Do Lithium-Oxygen Batteries Fail: Parasitic Chemical Reactions and Their Synergistic Effect.

10. Mechanism and performance of lithium-oxygen batteries - a perspective.

Review 5. Carbon Tube-Based Cathode for Li-CO₂ Batteries: A Review.

7. Material balance in the O₂ electrode of Li-O₂ cells with a porous carbon electrode and TEGDME-based electrolytes.