Interrogation of 2,2′-Bipyrimidines as Low-Potential Two-Electron Electrolytes

Griffin, Jeremy; Pancoast, Adam R.; Sigman, Matthew S.

doi:10.1021/jacs.0c11267

Cited by 35 publications

(61 citation statements)

References 56 publications

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“…Note, viologen anolyte materials are typically only cycled by one electron over the dication/radical cation oxidation states [40] . More recently there has been interest in harnessing two electrons from the viologen system, [41, 42] or finding other multi‐electron redox systems at highly negative or positive redox potentials [43–45] . Note, simple pyridinium/carbene hybrid molecules such as V (Figure 1) show significant decomposition after 25 cycles for two‐electron cycling in the symmetrical H‐cell [24a] …”

Section: Resultsmentioning

confidence: 99%

“…[40] More recently there has been interest in harnessing two electrons from the viologen system, [41,42] or finding other multi-electron redox systems at highly negative or positive redox potentials. [43][44][45] Note, simple pyridinium/carbene hybrid molecules such as V (Figure 1) show significant decomposition after 25 cycles for two-electron cycling in the symmetrical H-cell. [24a] To assess the electrochemical stability, we performed repetitive CV measurements for 2 a-2 c (Figure 12A).…”

Section: Methodsmentioning

confidence: 99%

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Organic Four‐Electron Redox Systems Based on Bipyridine and Phenanthroline Carbene Architectures

2022

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Novel organic redox systems that display multistage redox behaviour are highly sought‐after for a series of applications such as organic batteries or electrochromic materials. Here we describe a simple strategy to transfer well‐known two‐electron redox active bipyridine and phenanthroline architectures into novel strongly reducing four‐electron redox systems featuring fully reversible redox events with up to five stable oxidation states. We give spectroscopic and structural insight into the changes involved in the redox‐events and present characterization data on all isolated oxidation states. The redox‐systems feature strong UV/Vis/NIR polyelectrochromic properties such as distinct strong NIR absorptions in the mixed valence states. Two‐electron charge–discharge cycling studies indicate high electrochemical stability at strongly negative potentials, rendering the new redox architectures promising lead structures for multi‐electron anolyte materials.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Organic Four‐Electron Redox Systems Based on Bipyridine and Phenanthroline Carbene Architectures

2022

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“…[40] In jüngster Zeit ist das Interesse daran gewachsen, zwei Elektronen aus dem Viologensystem zu nutzen, [41,42] oder andere Mehrelektronen-Redoxsysteme mit stark negativen (oder positiven) Redoxpotentialen zu finden. [43][44][45] Es sei darauf hingewiesen, dass einfache Pyridinium/Carben-Hybridmoleküle wie V (Abbildung 1) nach 25 Zyklen eine erhebliche Zersetzung für zwei-Elektronen-Zyklen in der symmetrischen H-Zelle zeigen. [24a] Um die elektrochemische Stabilität zu bewerten, führten wir für À Anions des n-Bu 4 NPF 6 Elektrolyten führt.…”

Section: Ergebnisse Und Diskussionunclassified

Organische Vier‐Elektronen Redox‐Systeme basierend auf Bipyridin‐ und Phenanthrolin‐Carben‐Architekturen

2022

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Neuartige organische Redoxsysteme, die ein mehrstufiges Redoxverhalten aufweisen, sind für eine Reihe von Anwendungen von besonderem Interesse, wie z. B. organische Batterien oder elektrochrome Materialien. Hier beschreiben wir eine einfache Synthesestrategie, um bekannte zwei‐Elektronen redoxaktive Bipyridine in stark reduzierende vier‐Elektronen Redox‐Systeme zu überführen. Diese zeichnen sich durch eine vollständig reversible Redoxchemie sowie bis zu fünf isolierbare Oxidationsstufen aus. Wir geben strukturelle und spektroskopische Einblicke in die Redox‐Ereignisse begleitenden Änderungen und präsentieren Charakterisierungsdaten zu allen isolierten Oxidationszuständen. Die Redoxsysteme weisen starke UV/Vis/NIR polyelektrochrome Eigenschaften auf, wie z. B. ausgeprägte, intensive NIR‐Absorptionen in den gemischtvalenten Zuständen. Zwei‐Elektronen Ladungs/Entladungs‐Studien weisen auf eine hohe elektrochemische Stabilität bei stark negativen Potentialen hin, was die neuen Redox‐Architekturen zu vielversprechenden Leitstrukturen für Multi‐Elektronen Anolyt‐Materialien macht.

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“…Thus, it is essential to design molecules with high molar solubility in the solvent/electrolyte mixture. Techno-economical models have presented guidelines of around 100 Ah/L for the volumetric capacity of redox-active materials to present a viable alternative to aqueous technologies. , Recent work focuses on small molecules with single redox events. ,,,,,,− However, molecules with multiple redox events would increase the volumetric capacity. ,− Importantly, this should not go at the cost of other parameters such as solubility.…”

Section: Introductionmentioning

confidence: 99%

Imide-Based Multielectron Anolytes as High-Performance Materials in Nonaqueous Redox Flow Batteries

Daub

Janssen

Hendriks

2021

ACS Appl. Energy Mater.

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Recent developments toward high-energy-density all-organic redox flow batteries suggest the advantageous use of molecules exhibiting multielectron redox events. Following this approach, organic anolytes are developed that feature multiple consecutive one-electron reductions. These anolytes are based on N-methylphthalimide, which exhibits a single reversible reduction at a low potential with good cycling stability. Derivatives with two or three imide groups were synthesized to enable multielectron reduction events. By incorporating suitably designed side chains, a volumetric capacity of 65 Ah/L is achieved in electrolyte solutions. Bulk-electrolysis experiments and UV−vis−NIR absorption spectroscopy revealed good cycling stability for the first and second reduction of monoamides and diimides, respectively, but a loss of stability for the third reduction of triimides. We identify N-2-pentyl-N′-2-(2-(2methoxyethoxy)ethoxy)ethylaminepyromellitic diimide as a very promising multielectron anolyte with an excellent volumetric capacity and superior cycling and shelf-life stability compared to monoimides and triimides. The outstanding performance of this anolyte was demonstrated in proof-of-principle redox flow batteries that reach an energy density of 24.1 Wh/L.

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Interrogation of 2,2′-Bipyrimidines as Low-Potential Two-Electron Electrolytes

Cited by 35 publications

References 56 publications

Organic Four‐Electron Redox Systems Based on Bipyridine and Phenanthroline Carbene Architectures

Organic Four‐Electron Redox Systems Based on Bipyridine and Phenanthroline Carbene Architectures

Organische Vier‐Elektronen Redox‐Systeme basierend auf Bipyridin‐ und Phenanthrolin‐Carben‐Architekturen

Imide-Based Multielectron Anolytes as High-Performance Materials in Nonaqueous Redox Flow Batteries

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