The Dilemma of Supporting Electrolytes for Electroorganic Synthesis: A Case Study on Kolbe Electrolysis

The Dilemma of Supporting Electrolytes for Electroorganic Synthesis: A Case Study on Kolbe Electrolysis

Remarkably, coulombic efficiency (CE, about 50 % at 1 Farad equivalent), and product composition resulting from aqueous Kolbe electrolysis are independent of reactor temperature and initial pH value. Although numerous studies on Kolbe electrolysis are available, the interrelations of different react...

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Veröffentlicht in:ChemSusChem 2016-01, Vol.9 (1), p.50-60
Hauptverfasser: Stang, Carolin, Harnisch, Falk
Format: Artikel
Sprache:eng
Schlagworte:
Catalysis
Chemistry Techniques, Synthetic - methods
cyclic voltammetry
electrochemical oxidation
Electrochemistry
Electrodes
Electrolysis - methods
electrolytes
Electrolytes - chemistry
electrolytic conductivity
electroorganic synthesis
Hydrogen-Ion Concentration
Nitrates - chemistry
Pentanoic Acids - chemistry
Platinum - chemistry
Potassium Compounds - chemistry
Sulfates - chemistry
Temperature
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Harnisch, Falk
description Remarkably, coulombic efficiency (CE, about 50 % at 1 Farad equivalent), and product composition resulting from aqueous Kolbe electrolysis are independent of reactor temperature and initial pH value. Although numerous studies on Kolbe electrolysis are available, the interrelations of different reaction parameters (e.g., acid concentration, pH, and especially electrolytic conductivity) are not addressed. A systematic analysis based on cyclic voltammetry reveals that solely the electrolytic conductivity impacts the current–voltage behavior. When using supporting electrolytes, not only their concentration, but also the type is decisive. We show that higher concentrations of KNO3 result in reduced CE and thus in significant increase in electric energy demand per converted molecule, whereas Na2SO4 allows improved space–time yields. Pros and cons of adding supporting electrolytes are discussed in a final cost assessment. Salt in the electrosynthetic soup: Adding salts (supporting electrolytes) to aqueous solutions for electroorganic synthesis can solve and create dilemma related to reaction selectivity, space‐time yield, downstreaming, and electricity consumption. In this study, systematic analysis reveals that solely the electrolytic conductivity impacts the current–voltage behavior. The pros and cons of adding supporting electrolytes are discussed in a final cost assessment.
doi_str_mv 10.1002/cssc.201501407
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subjects Catalysis
Chemistry Techniques, Synthetic - methods
cyclic voltammetry
electrochemical oxidation
Electrochemistry
Electrodes
Electrolysis - methods
electrolytes
Electrolytes - chemistry
electrolytic conductivity
electroorganic synthesis
Hydrogen-Ion Concentration
Nitrates - chemistry
Pentanoic Acids - chemistry
Platinum - chemistry
Potassium Compounds - chemistry
Sulfates - chemistry
Temperature
title The Dilemma of Supporting Electrolytes for Electroorganic Synthesis: A Case Study on Kolbe Electrolysis
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