Tunable System for Electrochemical Reduction of Ketones and Phthalimides

Wang, Yaxin; Zhao, Jianyou; Qiao, Tianjiao; Zhang, Jian; Chen, G.

doi:10.1002/cjoc.202100508

Cited by 22 publications

(41 citation statements)

References 65 publications

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“…Sodium azide, used as a supporting electrolyte, was shown to have a positive effect on the oxidation of formic acid, as the electron transfer was enforced. When acetic acid was used instead of formic acid, diphenylmethanol was found as the main product from the hydrogenation of benzophenone [110] …”

Section: Anodic Counter Reactionsmentioning

confidence: 99%

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Counter Electrode Reactions—Important Stumbling Blocks on the Way to a Working Electro‐organic Synthesis

Klein

Waldvogel

2022

Angew Chem Int Ed

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Over the past two decades, electro‐organic synthesis has gained significant interest, both in technical and academic research as well as in terms of applications. The omission of stoichiometric oxidizers or reducing agents enables a more sustainable route for redox reactions in organic chemistry. Even if it is well‐known that every electrochemical oxidation is only viable with an associated reduction reaction and vice versa, the relevance of the counter reaction is often less addressed. In this Review, the importance of the corresponding counter reaction in electro‐organic synthesis is highlighted and how it can affect the performance and selectivity of the electrolytic conversion. A selection of common strategies and unique concepts to tackle this issue are surveyed to provide a guide to select appropriate counter reactions for electro‐organic synthesis.

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Section: Anodic Counter Reactionsmentioning

confidence: 99%

“…When acetic acid was used instead of formic acid, diphenylmethanol was found as the main product from the hydrogenation of benzophenone. [110] Another non-green but practical laboratory solution is the oxidation of sterically hindered amines. Xiang and coworkers reported the reduction of cyclic imides to hydroxylactams (Scheme 21).…”

Section: Anodic Additivesmentioning

confidence: 99%

Counter Electrode Reactions—Important Stumbling Blocks on the Way to a Working Electro‐organic Synthesis

Klein

Waldvogel

2022

Angew Chem Int Ed

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“…Bei Verwendung von Essigsäure anstelle von Ameisensäure wird Diphenylmethanol aus der Hydrierung von Benzophenon als Hauptprodukt beobachtet. [110] Eine weitere nicht nachhaltige, aber praktische Laborlösung ist die Oxidation von sterisch gehinderten Aminen. es ist sehr sauer und bildet nach dem Protonenaustausch mit dem Lösungsmittel neutrale Radikale.…”

Section: Anodische Additiveunclassified

“…Es hat sich gezeigt, dass Natriumazid als Leitsalz einen positiven Effekt auf die Oxidation von Formiat hat, da der Elektronentransfer bevorzugt wird. Bei Verwendung von Essigsäure anstelle von Ameisensäure wird Diphenylmethanol aus der Hydrierung von Benzophenon als Hauptprodukt beobachtet [110] …”

Section: Anodische Gegenreaktionenunclassified

Reaktionen an der Gegenelektrode – wichtige Stolpersteine auf dem Weg einer funktionierenden elektro‐organischen Synthese

Klein

Waldvogel

2022

Angewandte Chemie

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In den letzten zwei Jahrzehnten hat die elektro‐organische Synthese signifikant an Interesse gewonnen, sowohl in technischer und akademischer Forschung als auch in der Anwendung. Der Verzicht auf Oxidations‐ und Reduktionsmittel in stöchiometrischen Mengen ermöglicht eine nachhaltigere Alternative, Redoxreaktionen in der organischen Chemie durchzuführen. Auch wenn bekannt ist, dass jede elektrochemische Oxidation nur zusammen mit einer assoziierten Reduktion durchführbar ist und umgekehrt, wird die Relevanz der Gegenreaktion oft wenig beachtet. In diesem Aufsatz wird die Bedeutung der korrespondierenden Gegenreaktion beleuchtet und welchen Einfluss diese auf die Durchführbarkeit und Selektivität einer elektrochemischen Umsetzung hat. Anhand einer Auswahl üblicher Strategien und einzigartiger Konzepte werden Lösungen für dieses Problem aufgeführt. Dies ergibt einen Leitfaden zur Auswahl geeigneter Gegenreaktionen in der elektro‐organischen Synthese.

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“…Thus, the development of a sacrificial anode-free process such as paired electrolysis would be highly desirable [40][41][42][43][44]. The group of Wang recently reported the sacrificial anode-free electroreduction of benzophenone derivatives to afford vic-1,2-diols using over-stoichiometric NaN 3 under acidic conditions, but appropriate precau-tions should be taken for in situ-generated explosive and toxic HN 3 [45]. Kim et al reported the formation of vic-1,2-diols in the sacrificial anode-free electrocarboxylation of 1-phenylethanol and benzyl alcohol which involves tetramethylpiperidine-1-oxyl-mediated alcohol oxidation as an anodic event [46].…”

Section: Introductionmentioning

confidence: 99%

Electrochemical formal homocoupling of sec-alcohols

Yamamoto¹,

Arita²,

Shiota³

et al. 2022

Beilstein J. Org. Chem.

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Electrochemical pinacol coupling of carbonyl compounds in an undivided cell with a sacrificial anode would be a promising approach toward synthetically valuable vic-1,2-diol scaffolds without using low-valent metal reductants. However, sacrificial anodes produce an equimolar amount of metal waste, which may be a major issue in terms of sustainable chemistry. Herein, we report a sacrificial anode-free electrochemical protocol for the synthesis of pinacol-type vic-1,2-diols from sec-alcohols, namely benzyl alcohol derivatives and ethyl lactate. The corresponding vic-1,2-diols are obtained in moderate to good yields, and good to high levels of stereoselectivity are observed for sec-benzyl alcohol derivatives. The present transformations smoothly proceed in a simple undivided cell under constant current conditions without the use of external chemical oxidants/reductants, and transition-metal catalysts.

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Tunable System for Electrochemical Reduction of Ketones and Phthalimides

Cited by 22 publications

References 65 publications

Counter Electrode Reactions—Important Stumbling Blocks on the Way to a Working Electro‐organic Synthesis

Counter Electrode Reactions—Important Stumbling Blocks on the Way to a Working Electro‐organic Synthesis

Reaktionen an der Gegenelektrode – wichtige Stolpersteine auf dem Weg einer funktionierenden elektro‐organischen Synthese

Electrochemical formal homocoupling of sec-alcohols

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