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Electrochemical window

From Wikipedia, the free encyclopedia

The electrochemical window (EW) of a substance is the electrode electric potential range between which the substance is neither oxidized nor reduced. The EW is one of the most important characteristics to be identified for solvents and electrolytes used in electrochemical applications. The EW is a term that is commonly used to indicate the potential range and the potential difference. It is calculated by subtracting the reduction potential (cathodic limit) from the oxidation potential (anodic limit).[1]

When the substance of interest is water, it is often referred to as the water window.

This range is important for the efficiency of an electrode. Out of this range, the electrodes will react with the electrolyte, instead of driving the electrochemical reaction.[2]

In principle, ammonia has an extremely small electrochemical window, but thermodynamically-favored reactions less than 1 V outside the window are very slow. Consequently, the electrochemical window for many practical reactions is much larger, comparable to water.[3] Ionic liquids famously have a very large electrochemical window, about 4–5 V.[4]

The importance of electrochemical window (EW) in organic batteries

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The electrochemical window (EW) is an important concept in organic electrosynthesis and design of batteries, especially organic batteries.[5] This is because at higher voltage (greater than 4.0 V) organic electrolytes decompose and interferes with the oxidation and reduction of the organic cathode/anode materials. For this reason, the best organic electrolytes should be characterized by a wider range of electrochemical window, i.e., greater than the working range of the battery cell voltage.[6] For example, the electrochemical window of Lithium bis- (trifluoromethanesulfonyl)imide, commercially known as LiTFSI is about 3.0 V because it can operate in the range of 1.9 -4.9 V.[7] On the other hand, for electrolytes that are characterized by narrow electrochemical window, they are prone to irreversible decomposition,[8] which in turn triggers the battery capacity decaying during subsequent battery cycling.

The electrochemical window of organic electrolyte depends on many factors that include temperature, molecular frontier orbitals such LUMO (Lowest Unoccupied Molecular Orbital) and HOMO (Highest occupied Molecular Orbital) because the mechanisms of reduction (electron gaining) and oxidation (electron loss) are governed by band gap between HOMO and LUMO.[9] Solvation energy also plays an important role in defining the electrochemical window of the electrolyte.[10]

In order to safeguard the thermodynamic stability working conditions of the electrode materials in a given electrolyte, the electrochemical potentials of the electrode materials (anode and cathode) must be comprised within the electrochemical stability of the electrolyte.[11] This condition is very succinct because electrolyte might be oxidized when the cathode material possess an electrochemical potential, which is less than the electrolyte oxidation potential. When the electrochemical potential of the anode material is quite higher than the reduction potential of the electrolyte, the electrolyte will be degraded through reduction process.[12][13]

Limitation of Electrochemical window

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One of the shortcoming of electrochemical window (EW) in predicting the stability of the electrolyte towards anode or cathode materials ignores the voltage and the ionic conductivity, which are also important.[14]

References

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  1. ^ Maan Hayyan; Farouq S. Mjalli; Mohd Ali Hashim; Inas M. AlNashef (2013). "Investigating the Electrochemical Windows of Ionic Liquids". Journal of Industrial and Engineering Chemistry. 19: 106–112. doi:10.1016/j.jiec.2012.07.011.
  2. ^ Huggins, Robert (2010). Advanced batteries : materials science aspects. Springer. p. 375. ISBN 978-0-387-76423-8. OCLC 760155429.
  3. ^ Greenwood, Norman N.; Earnshaw, Alan (1984). Chemistry of the Elements. Oxford: Pergamon Press. p. 488. ISBN 978-0-08-022057-4.
  4. ^ "Ionic liquids". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. p. 551. doi:10.1002/14356007.l14_l01. ISBN 978-3527306732.
  5. ^ Leech, Matthew C.; Lam, Kevin (April 2022). "A practical guide to electrosynthesis". Nature Reviews Chemistry. 6 (4): 275–286. doi:10.1038/s41570-022-00372-y. ISSN 2397-3358. PMID 37117870. S2CID 247585645.
  6. ^ Li, Mengjie; Hicks, Robert Paul; Chen, Zifeng; Luo, Chao; Guo, Juchen; Wang, Chunsheng; Xu, Yunhua (2023-02-22). "Electrolytes in Organic Batteries". Chemical Reviews. 123 (4): 1712–1773. doi:10.1021/acs.chemrev.2c00374. ISSN 0009-2665. PMID 36735935. S2CID 256577160.
  7. ^ Li, Mengjie; Hicks, Robert Paul; Chen, Zifeng; Luo, Chao; Guo, Juchen; Wang, Chunsheng; Xu, Yunhua (2023-02-22). "Electrolytes in Organic Batteries". Chemical Reviews. 123 (4): 1712–1773. doi:10.1021/acs.chemrev.2c00374. ISSN 0009-2665. PMID 36735935. S2CID 256577160.
  8. ^ Li, Chenghan; Zhou, Shi; Dai, Lijie; Zhou, Xuanyi; Zhang, Biao; Chen, Liwen; Zeng, Tao; Liu, Yating; Tang, Yongfu; Jiang, Jie; Huang, Jianyu (2021-11-09). "Porous polyamine/PEO composite solid electrolyte for high performance solid-state lithium metal batteries". Journal of Materials Chemistry A. 9 (43): 24661–24669. doi:10.1039/D1TA04599G. ISSN 2050-7496. S2CID 240888672.
  9. ^ Marchiori, Cleber F. N.; Carvalho, Rodrigo P.; Ebadi, Mahsa; Brandell, Daniel; Araujo, C. Moyses (2020-09-08). "Understanding the Electrochemical Stability Window of Polymer Electrolytes in Solid-State Batteries from Atomic-Scale Modeling: The Role of Li-Ion Salts". Chemistry of Materials. 32 (17): 7237–7246. doi:10.1021/acs.chemmater.0c01489. ISSN 0897-4756. S2CID 225384562.
  10. ^ Wang, Da; He, Tingting; Wang, Aiping; Guo, Kai; Avdeev, Maxim; Ouyang, Chuying; Chen, Liquan; Shi, Siqi (March 2023). "A Thermodynamic Cycle‐Based Electrochemical Windows Database of 308 Electrolyte Solvents for Rechargeable Batteries". Advanced Functional Materials. 33 (11). doi:10.1002/adfm.202212342. ISSN 1616-301X. S2CID 255457966.
  11. ^ Marchiori, Cleber F. N.; Carvalho, Rodrigo P.; Ebadi, Mahsa; Brandell, Daniel; Araujo, C. Moyses (2020-09-08). "Understanding the Electrochemical Stability Window of Polymer Electrolytes in Solid-State Batteries from Atomic-Scale Modeling: The Role of Li-Ion Salts". Chemistry of Materials. 32 (17): 7237–7246. doi:10.1021/acs.chemmater.0c01489. ISSN 0897-4756. S2CID 225384562.
  12. ^ Sekhar Manna, Surya; Bhauriyal, Preeti; Pathak, Biswarup (2020). "Identifying suitable ionic liquid electrolytes for Al dual-ion batteries: role of electrochemical window, conductivity and voltage". Materials Advances. 1 (5): 1354–1363. doi:10.1039/D0MA00292E. S2CID 221802258.
  13. ^ Kalisa, Nyirimbibi Daniela; Muhizi, Theonestea; Niyotwizera, Jean Jacques Yvesa; Barutwanayo, Jean Baptistea; Nkuranga, Jean Boscoa (2020-05-08). "Kinetics and Thermodynamics Investigations on Corrosion Inhibiting Properties of Coffee Husks Extract on Mild Steel in Acidic Medium". Rwanda Journal of Engineering, Science, Technology and Environment. 3 (1). doi:10.4314/rjeste.v3i1.10. ISSN 2617-233X.
  14. ^ Sekhar Manna, Surya; Bhauriyal, Preeti; Pathak, Biswarup (2020). "Identifying suitable ionic liquid electrolytes for Al dual-ion batteries: role of electrochemical window, conductivity and voltage". Materials Advances. 1 (5): 1354–1363. doi:10.1039/D0MA00292E. S2CID 221802258.