TY - JOUR
T1 - Electrosynthesis of 2,3-butanediol and methyl ethyl ketone from acetoin in flow cells
AU - Ochoa-Gómez, José R.
AU - Fernández-Carretero, Francisco
AU - Río-Pérez, Francisca
AU - García-Luis, Alberto
AU - Roncal, Tomás
AU - García-Suárez, Eduardo J.
N1 - Publisher Copyright:
This journal is © The Royal Society of Chemistry.
PY - 2019
Y1 - 2019
N2 - Acetoin could shortly become a platform molecule due to current progress in fermentation technology, the megatrend for
shifting from an oil-based economy to one based on biomass, the quest for green manufacturing processes and its two
highly reactive carbonyl and hydroxyl moieties. In this paper, the successful electro-conversion of acetoin into two
valuable chemicals, 2,3-butandiol (2,3-BD) and methyl ethyl ketone (MEK), at constant electrical current in aqueous
phase at room temperature using both divided and undivided 20 cm2 filter-press flow cells under experimental conditions
suitable for industrial production is reported. Cathode material is the key parameter to drive the electroreduction towards
one or another chemical. 2,3-BD is the major chemical produced by electrohydrogenation when low hydrogen overvoltage
cathodes, such as Pt and Ni, of high surface area obtained by PVD coating on a carbon gas diffusion layer are used, while
MEK is the principal product produced by electrohydrogenolysis when high hydrogen overvoltage cathodes, such as
graphite, Pb and Cd foils, are employed. 2,3-BD and MEK can be obtained, respectively, in 92.8% and 85.7%
selectivities, 71.7% and 80.4% current efficiencies, with 1.21 and 1.08 kg.h-1.m-2 productivities and power consumptions
of 2.94 and 4.1 kWh.kg-1 using undivided cells and aqueous K2HPO4 electrolysis media at pHs of 3.6 and 5.5. The
reported electroconversion of acetoin is highly flexible because 2,3-BD and MEK can be produced by changing just the
cathode but using the same cell, with the same electrolyte at the same current density.
AB - Acetoin could shortly become a platform molecule due to current progress in fermentation technology, the megatrend for
shifting from an oil-based economy to one based on biomass, the quest for green manufacturing processes and its two
highly reactive carbonyl and hydroxyl moieties. In this paper, the successful electro-conversion of acetoin into two
valuable chemicals, 2,3-butandiol (2,3-BD) and methyl ethyl ketone (MEK), at constant electrical current in aqueous
phase at room temperature using both divided and undivided 20 cm2 filter-press flow cells under experimental conditions
suitable for industrial production is reported. Cathode material is the key parameter to drive the electroreduction towards
one or another chemical. 2,3-BD is the major chemical produced by electrohydrogenation when low hydrogen overvoltage
cathodes, such as Pt and Ni, of high surface area obtained by PVD coating on a carbon gas diffusion layer are used, while
MEK is the principal product produced by electrohydrogenolysis when high hydrogen overvoltage cathodes, such as
graphite, Pb and Cd foils, are employed. 2,3-BD and MEK can be obtained, respectively, in 92.8% and 85.7%
selectivities, 71.7% and 80.4% current efficiencies, with 1.21 and 1.08 kg.h-1.m-2 productivities and power consumptions
of 2.94 and 4.1 kWh.kg-1 using undivided cells and aqueous K2HPO4 electrolysis media at pHs of 3.6 and 5.5. The
reported electroconversion of acetoin is highly flexible because 2,3-BD and MEK can be produced by changing just the
cathode but using the same cell, with the same electrolyte at the same current density.
KW - Green manufacturing processes
KW - Acetoin
KW - Biomass
KW - Green chemistry
KW - Green manufacturing processes
KW - Acetoin
KW - Biomass
KW - Green chemistry
UR - http://www.scopus.com/inward/record.url?scp=85059679128&partnerID=8YFLogxK
U2 - 10.1039/C8GC03028F
DO - 10.1039/C8GC03028F
M3 - Article
SN - 1463-9262
VL - unknown
SP - 164
EP - 177
JO - Green Chemistry
JF - Green Chemistry
IS - 1
ER -