Recent Trends, Benchmarking, and Challenges of Electrochemical Reduction of CO₂ by Molecular Catalysts

Abstract: provides a promising alternative to hydrocarbon sources for petrochemical feedstock. Thanks to the electrochemical nature of the CO 2 conversion to fuels and chemicals, the electrical energy invested to convert CO 2 in the form of a chemical fuel can be stored and redistributed using established supply chains for future use. Additionally, the integration of renewable energy systems (green electricity) into the grid can potentially create a carbon neutral energy cycle, and when driven by solar energy, offers a … Show more

“…3a, right). 112 A comparable effect but opposite in sign was observed by replacing the trimethylanilinium substituents with negatively charged sulfonate groups (19), owing to unfavorable electrostatic interactions. Furthermore, the derivative bearing the quaternary ammonium groups in ortho positions (compound 20) exhibited a significant decrease of the catalytic overpotential while dramatically increasing the TOF (Fig.…”

“…about 0.03 M in common aqueous electrolytes, 0.31 M in CH 3 CN and 0.19 M in DMF 15 ) must be also carefully assessed. In the last decades, a plethora of transition metal-based catalysts have been reported for efficient CO 2 RR, ranging from molecular catalysts [16][17][18][19][20][21][22] to metal nanoparticles 23,24 and bulk heterogeneous materials. [25][26][27] In parallel, the increasing interest for in situ and operando microscopic and spectroelectrochemical (SEC) techniques applied to both, the homogeneous and heterogeneous systems has led to a strong improvement in the fundamental understanding of the factors governing the CO 2 RR process.…”

Transition metal-based catalysts for the electrochemical CO₂reduction: from atoms and molecules to nanostructured materials

“…3a, right). 112 A comparable effect but opposite in sign was observed by replacing the trimethylanilinium substituents with negatively charged sulfonate groups (19), owing to unfavorable electrostatic interactions. Furthermore, the derivative bearing the quaternary ammonium groups in ortho positions (compound 20) exhibited a significant decrease of the catalytic overpotential while dramatically increasing the TOF (Fig.…”

“…about 0.03 M in common aqueous electrolytes, 0.31 M in CH 3 CN and 0.19 M in DMF 15 ) must be also carefully assessed. In the last decades, a plethora of transition metal-based catalysts have been reported for efficient CO 2 RR, ranging from molecular catalysts [16][17][18][19][20][21][22] to metal nanoparticles 23,24 and bulk heterogeneous materials. [25][26][27] In parallel, the increasing interest for in situ and operando microscopic and spectroelectrochemical (SEC) techniques applied to both, the homogeneous and heterogeneous systems has led to a strong improvement in the fundamental understanding of the factors governing the CO 2 RR process.…”

Transition metal-based catalysts for the electrochemical CO₂reduction: from atoms and molecules to nanostructured materials

“…[ 5,7–9 ] The challenge exists in relieving dependence on fossil fuels and instead utilizing other alternative cleaner energy sources entirely, such as wind, solar, hydropower, and geothermal energy, which result in little or no carbon footprints. [ 1,2,10–13 ] Although active steps have been taken in this direction, such alternative sources are often transient in nature, inconsistent, and unpredictable, depending substantially on a large number of variables, such as location, timing, and environmental conditions [5] …”

Heterostructured Catalysts for Electrocatalytic and Photocatalytic Carbon Dioxide Reduction

“…(4-7)]. TiO 2 nanoparticles and other heterogeneous catalysts have been used to directly reduce CO 2 , along with a variety of metal-based catalysts and metal-organic frameworks [198][199][200][201][202][203]. However, selectivity for desired products is difficult to achieve.…”

Light‐driven catalysis with engineered enzymes and biomimetic systems