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

Klein, Martin; Waldvogel, Siegfried R.

doi:10.1002/anie.202204140

Cited by 58 publications

(52 citation statements)

References 238 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“… a Reaction conditions of undivided cell: 1a (1.0 mmol), anodic feedstock (1.0 mmol), n Bu 4 NBF 4 (1.0 mmol), and THF/H 2 O (4.5:0.5 mL) in an undivided cell with a platinum plate anode (10 mm × 10 mm × 0.1 mm) and a carbon plate cathode (10 mm × 10 mm × 1 mm), constant current = 20 mA ( j anode = 20 mA cm –2 ), r.t., 2.5 h (2.0 F/mol). Reaction conditions of divided cell: 1a (0.25 mmol), anodic feedstock (0.25 mmol), n Bu 4 NBF 4 (4.0 mmol), and THF/H 2 O (18:2 mL) in a divided cell with a FAB-PK-130 anion exchange membrane, constant current = 5 mA ( j anode = 5 mA cm –2 ), r.t., and 2.5 h (2.0 F/mol). b Collected from Figures and S1. c Conversion (%) determined by 1 H NMR using 1,3,5-trimethoxybenzene as an internal standard. d Isolated yield (%). e Collected from ref (vs SHE at 25 °C). See the Supporting Information for details. …”

Section: Resultsmentioning

confidence: 99%

“…10−15 Nevertheless, the counter reaction for electro-reductive organic transformations continues to pose a challenge, which usually involves either the oxygen evolution reaction (OER) or the sacrifice of the metal anode (Scheme 1B,1C). 7 The OER process requires relatively high overpotentials and restricts the overall efficiency of electrolysis due to its sluggish kinetics and thermodynamics. The use of sacrificial metal anode leads to excess generation of metal waste, complicated post-processing, and infeasible industrial scale-up.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Organic electrosynthesis has been revived as a powerful tool for chemical transformations and a sustainable alternative to conventional redox reactions over the past decade. − In a typical electrochemical cell, the power supply always pushes electrons into the cathode from the anode, leading to the coupled anodic oxidation and cathodic reduction. As such, the consideration of an appropriate counter reaction is relevant to ensure the high efficiency of the target electro-transformation. − For instance, the proton reduction with low overpotentials and favourable kinetics is often employed to satiate the cathodic process when an electro-oxidative organic transformation is of interest (Scheme A). − Nevertheless, the counter reaction for electro-reductive organic transformations continues to pose a challenge, which usually involves either the oxygen evolution reaction (OER) or the sacrifice of the metal anode (Scheme B,1C) . The OER process requires relatively high overpotentials and restricts the overall efficiency of electrolysis due to its sluggish kinetics and thermodynamics.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Discovery of Anodic Thiourea Oxidation as a Sustainable Counter Reaction to Boost Electro-Reductive Organic Transformations

Wang

Shonhe

et al. 2023

ACS Sustainable Chem. Eng.

View full text Add to dashboard Cite

In the reductive electrochemistry, the oxidative counter reaction remains one of the main bottlenecks for efficient cathodic organic transformations, but it has received less attention. Herein, anodic thiourea (TU) oxidation is reported as a sustainable oxidative counter reaction, which takes place at a low potential with a relative high current density. Mechanistic studies suggest that the anodic TU oxidation is initiated by a single electron-transfer (SET) process with the formation of formamidine disulfide cation as the main intermediate. In practice, the anodic TU oxidation counterbalances a series of SET reductive transformations at the cathode, and the protocol features sustainable condition, minimized waste, convenient setup, and excellent scalability, which highlights the underexplored potential of TU oxidation as an alternative counter reaction for the reductive electrochemistry.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Discovery of Anodic Thiourea Oxidation as a Sustainable Counter Reaction to Boost Electro-Reductive Organic Transformations

Wang

Shonhe

et al. 2023

ACS Sustainable Chem. Eng.

View full text Add to dashboard Cite

show abstract

“…When stable anode materials, such as platinum, glassy carbon, or boron-doped diamond, are used, reactions are usually carried out in divided cells to avoid unwanted oxidation of the starting material or product of the cathodic process . A typical anodic reaction occurring in systems with inert anodes is the oxidation of the solvent or supporting electrolyte anions . Several approaches have been pursued to avoid sacrificial anodes in electrocarboxylation reactions.…”

Section: Introductionmentioning

confidence: 99%

“…36 A typical anodic reaction occurring in systems with inert anodes is the oxidation of the solvent or supporting electrolyte anions. 37 Several approaches have been pursued to avoid sacrificial anodes in electrocarboxylation reactions. Muchez et al presented an undivided cell setup with a stable anode where the TEMPO (2,2,6,6-tetramethylpiperidinyloxyl)-mediated oxidation of benzyl alcohol to benzaldehyde is the anodic process.…”

Section: ■ Introductionmentioning

confidence: 99%

Electrochemical CO₂ Utilization for the Synthesis of α-Hydroxy Acids

Seidler

Roth

Vieira

et al. 2022

ACS Sustainable Chem. Eng.

Self Cite

View full text Add to dashboard Cite

The electrocarboxylation of organic compounds provides a green alternative to the conventional use of cyanides or organometallics. Via a simple electrochemical approach, CO 2 can be directly incorporated into aldehydes or ketones to form αhydroxy acids using electrical energy as a driving force. In this study, propylene carbonate was used as a "green" solvent. Importantly, the use of sacrificial anodes was avoided; instead, cost-efficient and stable graphite anodes were applied. Voltammetric studies on benzaldehyde carboxylation revealed that the presence of CO 2 significantly changes the reduction behavior of benzaldehyde at potentials more negative than the potential of the ketyl radical formation. Bulk electrolysis was performed in various solvents and supporting electrolyte systems, leading to more than 55% mandelic acid yield in propylene carbonate. Among the tested solvents (acetonitrile, N,N-dimethylformamide, dimethyl sulfoxide, and propylene carbonate), propylene carbonate resulted in the highest carboxylate yield. Numerous cathode materials were tested. High carboxylate yields were achieved using graphite, glassy carbon, and lead cathodes. The reaction was successfully carried out for various aromatic aldehydes and ketones as substrates, providing yields of up to 63%.

show abstract

Degradation of Lignosulfonate to Vanillic Acid Using Ferrate

Klein

Kupec

Stöckl

et al. 2022

Advanced Sustainable Systems

Self Cite

View full text Add to dashboard Cite

high technical interest as renewable and biobased feedstock [7] due to their aromatic backbone and high availability. [8][9][10][11] Consequently, the targeted degradation of the respective lignin fractions to value-added products is highly desired. [12,13] The difficulty of this process lies in the different functionalization and the structure of the polyphenolic backbone, which depends on many factors such as pulping process, harvesting time, and type of tree. [10,14] Therefore, the industry uses only small fractions for further production, while the majority is incinerated to recover energy costs. [4,9] Lignin, as a renewable feedstock, offers a promising alternative to petroleum refining and shows tremendous potential for bio-based products such as surfactants and fine chemicals. [5,13,15] Nevertheless, selective degradation is challenging, and several studies focused on this complex topic to degrade lignin into value-added products such as aromatic intermediates. [8,[16][17][18] Lignin degradation shows a broad and diverse spectrum of products, such as aldehydes, [19][20][21]22] alcohols, [21] arenes, [18,23,24] quinones, [25] and carboxylic acids, [16,26,27] obtained in previous research. Different metal-based catalysts were studied to improve degradation and increase selectivity including noble metals like ruthenium, palladium, and platinum. [28] The disadvantages of these processes are the very high costs and limited availability of the metals, which might also cause uncontrolled over-hydrogenation, decreasing the yield of the phenolic products. Another approach is using ionic liquids as solvents in combination with catalysts or oxidizers. [29] However, the high costs for ionic liquids restrict their application for industrial operations. Additionally, the separation process is complex due to interactions with aromatic moieties of residual lignin.Promising electrochemical pathways are reported to yield aldehydes, [3,21,30] carboxylic acids, [27,31] and other phenolic products in good yields. [19,21,27,30] These methods are cost-effective and environmentally friendly. [32] Also, a well-known alternative is the use of oxidizers for lignin degradation. [3,20,23] However, only a few oxidizers, such as periodate, [3] nitrobenzene, [33,34] or hydrogen peroxide, [35] have high availability, and are safe in handling. Moreover, lignin conversion is not limited to the electrode surface since the respective oxidizers are dissolved. The monomer yields out of lignin using oxidizers vary significantly due to different wood types and experimental conditions. In a previous report, we showed that platform oxidizers, such as periodate, are highly beneficial for lignin degradation. This method significantly improves the vanillin yield (8.9 wt%) or selectively produces 5-iodovanillin using different workup conditions. [3] A new method is presented using electrochemically generated ferrate to degrade the technically relevant bio-based side-stream products, lignin and lignosulfonate. An exclusive degradation to vanillic ac...

show abstract

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

Cited by 58 publications

References 238 publications

Discovery of Anodic Thiourea Oxidation as a Sustainable Counter Reaction to Boost Electro-Reductive Organic Transformations

Discovery of Anodic Thiourea Oxidation as a Sustainable Counter Reaction to Boost Electro-Reductive Organic Transformations

Electrochemical CO₂ Utilization for the Synthesis of α-Hydroxy Acids

Degradation of Lignosulfonate to Vanillic Acid Using Ferrate

Contact Info

Product

Resources

About

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

Cited by 58 publications

References 238 publications

Discovery of Anodic Thiourea Oxidation as a Sustainable Counter Reaction to Boost Electro-Reductive Organic Transformations

Discovery of Anodic Thiourea Oxidation as a Sustainable Counter Reaction to Boost Electro-Reductive Organic Transformations

Electrochemical CO2 Utilization for the Synthesis of α-Hydroxy Acids

Degradation of Lignosulfonate to Vanillic Acid Using Ferrate

Contact Info

Product

Resources

About

Electrochemical CO₂ Utilization for the Synthesis of α-Hydroxy Acids