Resumen
H2020 LOTER.CO2M project aims to develop advanced, low-cost electro-catalysts and membranes for the direct electrochemical
reduction of CO2 to methanol by low temperature CO2-H2O co-electrolysis. The materials will be developed
using sustainable, non-toxic and non-critical raw materials. They will be scaled-up, integrated into a gas phase
electrochemical reactor, and the process validated for technical and economic feasibility under industrially relevant
conditions. The produced methanol can be used as a chemical feedstock or for effective chemical storage of renewable
energy.
The demonstration of the new materials at TRL5 level, and the potential of this technology for market
penetration, will be assessed by achieving a target electrochemical performance > 50 A/g at 1.5 V/cell, a CO2
conversion rate > 60%, and a selectivity > 90% towards methanol production with an enthalpy efficiency for the
process > 86%. A significant increase in durability under intermittent operation in combination with renewable
power sources is also targeted in the project through several stabilization strategies to achieve a degradation rate of <
1%/1000 h at stack level. The developed low-temperature CO2 conversion reactor will offer fast response (frequency
> 2-5 Hz) to electrical current fluctuations typical of intermittent power sources and a wide operating range in terms
of input power, i.e. from 10% to full power in less than a second. Such aspects are indicative of an excellent dynamic
behaviour as necessary to operate with renewable power sources. A life cycle assessment of the CO2 electrolysis
system, which will compile information at different levels from materials up to the CO2 electrolysis system including
processing resources, will complete the assessment of this technology for large-scale application. Field testing of the
co-electrolysis system in an industrial relevant environment will enable to evaluate the commercial competitiveness
and the development of a forward exploitation plan.