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Article: Redox-Active Macrocycles for Organic Rechargeable Batteries

TitleRedox-Active Macrocycles for Organic Rechargeable Batteries
Authors
Issue Date2017
Citation
Journal of the American Chemical Society, 2017, v. 139, n. 19, p. 6635-6643 How to Cite?
AbstractOrganic rechargeable batteries, composed of redox-active molecules, are emerging as candidates for the next generation of energy storage materials because of their large specific capacities, cost effectiveness, and the abundance of organic precursors, when compared with conventional lithium-ion batteries. Although redox-active molecules often display multiple redox states, precise control of a molecule's redox potential, leading to a single output voltage in a battery, remains a fundamental challenge in this popular field of research. By combining macrocyclic chemistry with density functional theory calculations (DFT), we have identified a structural motif that more effectively delocalizes electrons during lithiation events in battery operations - namely, through-space electron delocalization in triangular macrocyclic molecules that exhibit a single well-defined voltage profile - compared to the discrete multiple voltage plateaus observed for a homologous macrocyclic dimer and an acyclic derivative of pyromellitic diimide (PMDI). The triangular macrocycle, incorporating three PMDI units in close proximity to one another, exhibits a single output voltage at 2.33 V, compared with two peaks at (i) 2.2 and 1.95-1.60 V for reduction and (ii) 1.60-1.95 and 2.37 V for oxidation of the acyclic PMDI derivative. By investigating the two cyclic derivatives with different conformational dispositions of their PMDI units and the acyclic PMDI derivative, we identified noticeable changes in interactions between the PMDI units in the two cyclic derivatives under reducing conditions, as determined by differential pulse voltammetry, solution-state spectroelectrochemistry, and variable-temperature UV-Vis spectra. The numbers and relative geometries of the PMDI units are found to alter the voltage profile of the active materials significantly during galvanostatic measurements, resulting in a desirable single plateau for the triangular macrocycle. The present investigation reveals that understanding and controlling the relative conformational dispositions of redox-active units in macrocycles are key to achieving high energy density and long cycle-life electrodes for organic rechargeable batteries.
Persistent Identifierhttp://hdl.handle.net/10722/333275
ISSN
2023 Impact Factor: 14.4
2023 SCImago Journal Rankings: 5.489
ISI Accession Number ID

 

DC FieldValueLanguage
dc.contributor.authorKim, Dong Jun-
dc.contributor.authorHermann, Keith R.-
dc.contributor.authorProkofjevs, Aleksandrs-
dc.contributor.authorOtley, Michael T.-
dc.contributor.authorPezzato, Cristian-
dc.contributor.authorOwczarek, Magdalena-
dc.contributor.authorStoddart, J. Fraser-
dc.date.accessioned2023-10-06T05:18:04Z-
dc.date.available2023-10-06T05:18:04Z-
dc.date.issued2017-
dc.identifier.citationJournal of the American Chemical Society, 2017, v. 139, n. 19, p. 6635-6643-
dc.identifier.issn0002-7863-
dc.identifier.urihttp://hdl.handle.net/10722/333275-
dc.description.abstractOrganic rechargeable batteries, composed of redox-active molecules, are emerging as candidates for the next generation of energy storage materials because of their large specific capacities, cost effectiveness, and the abundance of organic precursors, when compared with conventional lithium-ion batteries. Although redox-active molecules often display multiple redox states, precise control of a molecule's redox potential, leading to a single output voltage in a battery, remains a fundamental challenge in this popular field of research. By combining macrocyclic chemistry with density functional theory calculations (DFT), we have identified a structural motif that more effectively delocalizes electrons during lithiation events in battery operations - namely, through-space electron delocalization in triangular macrocyclic molecules that exhibit a single well-defined voltage profile - compared to the discrete multiple voltage plateaus observed for a homologous macrocyclic dimer and an acyclic derivative of pyromellitic diimide (PMDI). The triangular macrocycle, incorporating three PMDI units in close proximity to one another, exhibits a single output voltage at 2.33 V, compared with two peaks at (i) 2.2 and 1.95-1.60 V for reduction and (ii) 1.60-1.95 and 2.37 V for oxidation of the acyclic PMDI derivative. By investigating the two cyclic derivatives with different conformational dispositions of their PMDI units and the acyclic PMDI derivative, we identified noticeable changes in interactions between the PMDI units in the two cyclic derivatives under reducing conditions, as determined by differential pulse voltammetry, solution-state spectroelectrochemistry, and variable-temperature UV-Vis spectra. The numbers and relative geometries of the PMDI units are found to alter the voltage profile of the active materials significantly during galvanostatic measurements, resulting in a desirable single plateau for the triangular macrocycle. The present investigation reveals that understanding and controlling the relative conformational dispositions of redox-active units in macrocycles are key to achieving high energy density and long cycle-life electrodes for organic rechargeable batteries.-
dc.languageeng-
dc.relation.ispartofJournal of the American Chemical Society-
dc.titleRedox-Active Macrocycles for Organic Rechargeable Batteries-
dc.typeArticle-
dc.description.naturelink_to_subscribed_fulltext-
dc.identifier.doi10.1021/jacs.7b01209-
dc.identifier.pmid28437104-
dc.identifier.scopuseid_2-s2.0-85019602876-
dc.identifier.volume139-
dc.identifier.issue19-
dc.identifier.spage6635-
dc.identifier.epage6643-
dc.identifier.eissn1520-5126-
dc.identifier.isiWOS:000401781900025-

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