Chemistry:Electrosynthesis

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Short description: Synthesis of chemical compounds in an electrochemical cell


In electrochemistry, electrosynthesis is the synthesis of chemical compounds in an electrochemical cell.[1][2][3][4] Compared to ordinary redox reactions, electrosynthesis sometimes offers improved selectivity and yields. Electrosynthesis is actively studied as a science and also has industrial applications. Electrooxidation has potential for wastewater treatment as well.

Experimental setup

The basic setup in electrosynthesis is a galvanic cell, a potentiostat and two electrodes. Typical solvent and electrolyte combinations minimizes electrical resistance.[5] Protic conditions often use alcohol-water or dioxane-water solvent mixtures with an electrolyte such as a soluble salt, acid or base. Aprotic conditions often use an organic solvent such as acetonitrile or dichloromethane with electrolytes such as lithium perchlorate or tetrabutylammonium salts. The choice of electrodes with respect to their composition and surface area can be decisive.[6] For example, in aqueous conditions the competing reactions in the cell are the formation of oxygen at the anode and hydrogen at the cathode. In this case a graphite anode and lead cathode could be used effectively because of their high overpotentials for oxygen and hydrogen formation respectively. Many other materials can be used as electrodes. Other examples include platinum, magnesium, mercury (as a liquid pool in the reactor), stainless steel or reticulated vitreous carbon. Some reactions use a sacrificial electrode that is consumed during the reaction like zinc or lead. Cell designs can be undivided cell or divided cell type. In divided cells the cathode and anode chambers are separated with a semiporous membrane. Common membrane materials include sintered glass, porous porcelain, polytetrafluoroethene or polypropylene. The purpose of the divided cell is to permit the diffusion of ions while restricting the flow of the products and reactants. This separation simplifies workup. An example of a reaction requiring a divided cell is the reduction of nitrobenzene to phenylhydroxylamine, where the latter chemical is susceptible to oxidation at the anode.

Reactions

Organic oxidations take place at the anode. Compounds are reduced at the cathode. Radical intermediates are often invoked. The initial reaction takes place at the surface of the electrode and then the intermediates diffuse into the solution where they participate in secondary reactions.

The yield of an electrosynthesis is expressed both in terms of the chemical yield and current efficiency. Current efficiency is the ratio of Coulombs consumed in forming the products to the total number of Coulombs passed through the cell. Side reactions decrease the current efficiency.

The potential drop between the electrodes determines the rate constant of the reaction. Electrosynthesis is carried out with either constant potential or constant current. The reason one chooses one over the other is due to a trade-off of ease of experimental conditions versus current efficiency. Constant potential uses current more efficiently because the current in the cell decreases with time due to the depletion of the substrate around the working electrode (stirring is usually necessary to decrease the diffusion layer around the electrode). This is not the case under constant current conditions, however. Instead, as the substrate's concentration decreases the potential across the cell increases in order to maintain the fixed reaction rate. This consumes current in side reactions produced outside the target voltage.

Anodic oxidations

  • A well-known electrosynthesis is the Kolbe electrolysis, in which two carboxylic acids decarboxylate, and the remaining structures bond together:
Electrólisis de Kolbe.png
  • A variation is called the non-Kolbe reaction when a heteroatom (nitrogen or oxygen) is present at the α-position. The intermediate oxonium ion is trapped by a nucleophile, usually solvent.
NonKolbe Reaction
  • Anodic electrosynthesis oxidize primary aliphatic amine to nitrile.[7]
  • Amides can be oxidized to N-acyliminium ions, which can be captured by various nucleophiles, for example:
Shono oxidation
This reaction type is called a Shono oxidation. An example is the α-methoxylation of N-carbomethoxypyrrolidine[8]
Anodic Silver(II) oxide oxidation of alpha-amino acids to nitriles

Cathodic reductions

Electrochemical version of the Markó-Lam deoxygenation
2 CH
2
=CHCN + 2 e
+ 2 H+
→ NC(CH
2
)
4
CN
In practice,the cathodic hydrodimerization of activated olefins is applied industrially in the synthesis of adiponitrile from two equivalents of acrylonitrile :
Adiponitrile Synthesis
  • The cathodic reduction of arene compounds to the 1,4-dihydro derivatives is similar to a Birch reduction. Examples from industry are the reduction of phthalic acid:
reduction of phthalic acid

and the reduction of 2-methoxynaphthalene:

Electrosynthesis tetral
Tafel rearrangement
Benzyl cyanide electrolytic reduction.png
  • Cathodic reduction of a nitroalkene can give the oxime in good yield. At higher negative reduction potentials, the nitroalkene can be reduced further, giving the primary amine but with lower yield.[17]
Nitroalkene-oxime-electroreduction.png
Nitroalkene-amine-electroreduction.png
380px
HCO
3
+ H
2
O + 2e
→ HCO
2
+ 2OH

or

CO
2
+ H
2
O + 2e
→ HCO
2
+ OH

If the feed is CO
2
and oxygen is evolved at the anode, the total reaction is:

CO
2
+ OH
→ HCO
2
+ 1
/
2
O
2

Redox reactions

Electrofluorination

In organofluorine chemistry, many perfluorinated compounds are prepared by electrochemical synthesis, which is conducted in liquid HF at voltages near 5–6 V using Ni anodes. The method was invented in the 1930s.[25] Amines, alcohols, carboxylic acids, and sulfonic acids are converted to perfluorinated derivatives using this technology. A solution or suspension of the hydrocarbon in hydrogen fluoride is electrolyzed at 5–6 V to produce high yields of the perfluorinated product.

See also

External links

  • Electrochemistry Encyclopedia Link

References

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  22. Bouwman, Elisabeth; Angamuthu, Raja; Byers, Philip; Lutz, Martin; Spek, Anthony L. (15 July 2010). "Electrocatalytic CO2 Conversion to Oxalate by a Copper Complex". Science 327 (5393): 313–315. doi:10.1126/science.1177981. PMID 20075248. Bibcode2010Sci...327..313A. 
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  25. Simons, J. H. (1949). "Production of Fluorocarbons I. The Generalized Procedure and its Use with Nitrogen Compounds". Journal of the Electrochemical Society 95: 47–52. doi:10.1149/1.2776733.  See also related articles by Simons et al. on pages 53, 55, 59, and 64 of the same issue.