The first examples of CO2RR are from the 19th century, when carbon dioxide was reduced to carbon monoxide using a zinccathode. Research in this field intensified in the 1980s following the oil embargoes of the 1970s. As of 2021, pilot-scale carbon dioxide electrochemical reduction is being developed by several companies, including Siemens,[3]Dioxide Materials,[4][5]Twelve and GIGKarasek. The techno-economic analysis was recently conducted to assess the key technical gaps and commercial potentials of the carbon dioxide electrolysis technology at near ambient conditions.[6][7]
CO2RR electrolyzers have been developed to reduce other forms of CO2 including [bi]carbonates sourced from CO2 captured directly from the air using strong alkalis like KOH [8] or carbamates sourced from flue gas effluents using alkali or amine-based absorbents like MEA or DEA.[9] While the techno-economics of these systems are not yet feasible, they provide a near net carbon neutral pathway to produce commodity chemicals like ethylene at industrially relavant scales.[10]
Chemicals from carbon dioxide
In carbon fixation, plants convert carbon dioxide into sugars, from which many biosynthetic pathways originate. The catalyst responsible for this conversion, RuBisCO, is the most common protein. Some anaerobic organisms employ enzymes to convert CO2 to carbon monoxide, from which fatty acids can be made.[11]
In industry, a few products are made from CO2, including urea, salicylic acid, methanol, and certain inorganic and organic carbonates.[12] In the laboratory, carbon dioxide is sometimes used to prepare carboxylic acids in a process known as carboxylation. An electrochemical CO2 electrolyzer that operates at room temperature has not yet been commercialized. Elevated temperature solid oxide electrolyzer cells (SOECs) for CO2 reduction to CO are commercially available. For example, Haldor Topsoe offers SOECs for CO2 reduction with a reported 6-8 kWh per Nm3[note 1] CO produced and purity up to 99.999% CO.[13]
Electrocatalysis
The electrochemical reduction of carbon dioxide to various products is usually described as:
The redox potentials for these reactions are similar to that for hydrogen evolution in aqueous electrolytes, thus electrochemical reduction of CO2 is usually competitive with hydrogen evolution reaction.[2]
Electrochemical methods have gained significant attention:
at ambient pressure and room temperature;
in connection with renewable energy sources (see also solar fuel)
competitive controllability, modularity and scale-up are relatively simple.[15]
The electrochemical reduction or electrocatalytic conversion of CO2 can produce value-added chemicals such methane, ethylene, ethanol, etc., and the products are mainly dependent on the selected catalysts and operating potentials (applying reduction voltage). A variety of homogeneous and heterogeneous catalysts[16] have been evaluated.[17][2]
Many such processes are assumed to operate via the intermediacy of metal carbon dioxide complexes.[18] Many processes suffer from high overpotential, low current efficiency, low selectivity, slow kinetics, and/or poor catalyst stability.[19]
The composition of the electrolyte can be decisive.[20][21][22] Gas-diffusion electrodes are beneficial.[23][24][25]
Three common products are carbon monoxide, formate, or higher order carbon products (two or more carbons).[30]
Carbon monoxide-producing
Carbon monoxide can be produced from CO2RR over various precious metal catalysts.[31] Steel has proven to be one such catalyst.,[32] or hydrogen.[33]
Mechanistically, carbon monoxide arises from the metal bonded to the carbon of CO2 (see metallacarboxylic acid). Oxygen is lost as water.[34]
Formate/formic acid-producing
Formic acid is produced as a primary product from CO2RR over diverse catalysts.[35]
Catalysts that promote Formic Acid production from CO2 operate by strongly binding to both oxygen atoms of CO2, allowing protons to attack the central carbon. After attacking the central carbon, one proton attaching to an oxygen results in the creation of formate.[34] Indium catalysts promote formate production because the Indium-Oxygen binding energy is stronger than the Indium-Carbon binding energy.[36] This promotes the production of formate instead of Carbon Monoxide.
C>1-producing catalysts
Copper electrocatalysts produce multicarbon compounds from CO2. These include C2 products (ethylene, ethanol, acetate, etc.) and even C3 products (propanol, acetone, etc.)[37] These products are more valuable than C1 products, but the current efficiencies are low.[38]
^ abCenti G, Perathoner S (2009). "Opportunities and prospects in the chemical recycling of carbon dioxide to fuels". Catalysis Today. 148 (3–4): 191–205. doi:10.1016/j.cattod.2009.07.075.
^Benson EE, Kubiak CP, Sathrum AJ, Smieja JM (January 2009). "Electrocatalytic and homogeneous approaches to conversion of CO2 to liquid fuels". Chemical Society Reviews. 38 (1): 89–99. doi:10.1039/b804323j. PMID19088968. S2CID20705539.
^Halmann MM, Steinberg M (May 1998). Greenhouse gas carbon dioxide mitigation: science and technology. CRC press. ISBN1-56670-284-4.
^Qiao J, Liu Y, Hong F, Zhang J (January 2014). "A review of catalysts for the electroreduction of carbon dioxide to produce low-carbon fuels". Chemical Society Reviews. 43 (2): 631–75. doi:10.1039/c3cs60323g. PMID24186433.