Atomic Layer Deposition of Cu Electrocatalysts on Gas Diffusion Electrodes for CO₂ Reduction

“…To achieve the formation and selectivity of C 2+ products with longer electroreduction times, Lenef and co-workers, for the first time, demonstrated the use of ALD Cu as the sole active catalyst, which was fabricated using plasma-enhanced ALD (PEALD) and deposited on 3D porous carbon GDE. 330 This approach allows for the fabrication of tunable catalyst size and loading, ensuring a conformal coating deep into the 3D electrode surface without clogging the surface pores. The electrochemical CO 2 reduction revealed the PEALD Cu catalyst deposited with 510 cycles produced a remarkable total FE of 75.2% for C 2+ products including FE of 42.2% for C 2 H 4 at −0.94 V vs. RHE (Fig.…”

Atomic/molecular layer deposition strategies for enhanced CO₂ capture, utilisation and storage materials

“…To achieve the formation and selectivity of C 2+ products with longer electroreduction times, Lenef and co-workers, for the first time, demonstrated the use of ALD Cu as the sole active catalyst, which was fabricated using plasma-enhanced ALD (PEALD) and deposited on 3D porous carbon GDE. 330 This approach allows for the fabrication of tunable catalyst size and loading, ensuring a conformal coating deep into the 3D electrode surface without clogging the surface pores. The electrochemical CO 2 reduction revealed the PEALD Cu catalyst deposited with 510 cycles produced a remarkable total FE of 75.2% for C 2+ products including FE of 42.2% for C 2 H 4 at −0.94 V vs. RHE (Fig.…”

Atomic/molecular layer deposition strategies for enhanced CO₂ capture, utilisation and storage materials

Atomically Dispersed Metal Catalysts for the Conversion of CO₂ into High‐Value C₂₊ Chemicals

Transition metal (Fe, Co, Ni)-doped cuprous oxide nanowire arrays as self-supporting catalysts for electrocatalytic CO2 reduction reaction to ethylene