Decoupling Conductivity and Solubility in Electrolytes Using Microemulsions

Jing Peng; Nelly M. Cantillo; Ye Xiao; K. McKensie Nelms; Lacey S. Roberts; Gabriel Goenaga; Adam Imel; Brian Andrew Barth; Mark Dadmun; Douglas G. Hayes; Thomas Zawodzinski

doi:10.1149/1945-7111/ac180b

Decoupling Conductivity and Solubility in Electrolytes Using Microemulsions

Jing Peng
, Nelly M. Cantillo
, Ye Xiao
, K. McKensie Nelms
, Lacey S. Roberts
, Gabriel Goenaga
, Adam Imel
, Brian Andrew Barth
, Mark Dadmun
, Douglas G. Hayes
, Thomas Zawodzinski

Producción científica: Contribución a revista › Artículo de Investigación › revisión exhaustiva

17 Citas (Scopus)

Resumen

Redox flow batteries have recently received considerable attention as possible large-scale energy storage devices, but their low energy density has inhibited widespread application. In this work, a novel strategy of decoupling conductivity and solubility of electrolytes using microemulsion is put forward to enhance ionic conduction of non-aqueous electrolytes, increase the selectivity of active species, improve the battery voltage, and eventually achieve the possibility of high energy density. We report a study of the electrochemistry of ferrocene in single phase Tween® 20/1-butanol/H 2 O/toluene microemulsion system at 20 C. At low and intermediate surfactant to water weight ratios (< 0.5/0.5), the voltammogram exhibits reversible electrochemical behavior, while at high surfactant levels the curves show lower levels of reversibility. The latter voltammograms have a form typically associated with high resistance in …

Idioma original	Inglés estadounidense
Publicación	Journal of the Electrochemical Society
DOI	https://doi.org/10.1149/1945-7111/ac180b
Estado	Publicada - ago. 4 2021
Publicado de forma externa	Sí

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ODS 7: Energía asequible y no contaminante

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Energías renovables, sostenibilidad y medio ambiente

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title = "Decoupling Conductivity and Solubility in Electrolytes Using Microemulsions",

abstract = "Redox flow batteries have recently received considerable attention as possible large-scale energy storage devices, but their low energy density has inhibited widespread application. In this work, a novel strategy of decoupling conductivity and solubility of electrolytes using microemulsion is put forward to enhance ionic conduction of non-aqueous electrolytes, increase the selectivity of active species, improve the battery voltage, and eventually achieve the possibility of high energy density. We report a study of the electrochemistry of ferrocene in single phase Tween{\textregistered} 20/1-butanol/H 2 O/toluene microemulsion system at 20 C. At low and intermediate surfactant to water weight ratios (< 0.5/0.5), the voltammogram exhibits reversible electrochemical behavior, while at high surfactant levels the curves show lower levels of reversibility. The latter voltammograms have a form typically associated with high resistance in … ",

author = "Jing Peng and Cantillo, \{Nelly M.\} and Ye Xiao and Nelms, \{K. McKensie\} and Roberts, \{Lacey S.\} and Gabriel Goenaga and Adam Imel and Barth, \{Brian Andrew\} and Mark Dadmun and Hayes, \{Douglas G.\} and Thomas Zawodzinski",

year = "2021",

month = aug,

day = "4",

doi = "10.1149/1945-7111/ac180b",

language = "English (US)",

journal = "Journal of the Electrochemical Society",

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AU - Peng, Jing

AU - Cantillo, Nelly M.

AU - Xiao, Ye

AU - Nelms, K. McKensie

AU - Roberts, Lacey S.

AU - Goenaga, Gabriel

AU - Imel, Adam

AU - Barth, Brian Andrew

AU - Dadmun, Mark

AU - Hayes, Douglas G.

AU - Zawodzinski, Thomas

PY - 2021/8/4

Y1 - 2021/8/4

N2 - Redox flow batteries have recently received considerable attention as possible large-scale energy storage devices, but their low energy density has inhibited widespread application. In this work, a novel strategy of decoupling conductivity and solubility of electrolytes using microemulsion is put forward to enhance ionic conduction of non-aqueous electrolytes, increase the selectivity of active species, improve the battery voltage, and eventually achieve the possibility of high energy density. We report a study of the electrochemistry of ferrocene in single phase Tween® 20/1-butanol/H 2 O/toluene microemulsion system at 20 C. At low and intermediate surfactant to water weight ratios (< 0.5/0.5), the voltammogram exhibits reversible electrochemical behavior, while at high surfactant levels the curves show lower levels of reversibility. The latter voltammograms have a form typically associated with high resistance in …

AB - Redox flow batteries have recently received considerable attention as possible large-scale energy storage devices, but their low energy density has inhibited widespread application. In this work, a novel strategy of decoupling conductivity and solubility of electrolytes using microemulsion is put forward to enhance ionic conduction of non-aqueous electrolytes, increase the selectivity of active species, improve the battery voltage, and eventually achieve the possibility of high energy density. We report a study of the electrochemistry of ferrocene in single phase Tween® 20/1-butanol/H 2 O/toluene microemulsion system at 20 C. At low and intermediate surfactant to water weight ratios (< 0.5/0.5), the voltammogram exhibits reversible electrochemical behavior, while at high surfactant levels the curves show lower levels of reversibility. The latter voltammograms have a form typically associated with high resistance in …

U2 - 10.1149/1945-7111/ac180b

DO - 10.1149/1945-7111/ac180b

M3 - Research Article

SN - 0013-4651

JO - Journal of the Electrochemical Society

JF - Journal of the Electrochemical Society

ER -

Decoupling Conductivity and Solubility in Electrolytes Using Microemulsions

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