Bimetallic NiMo oxides coupled with 3D CuxO nanorods for efficient overall water splitting

“…Table 4 introduces the electrocatalytic activity of our fabricated ternary catalyst in contrast to the reported ternary structures of similar components. Our fabricated ternary electrocatalystis of comparable performance to (Cu x Mo x /Co 1−x NPs@RGO deposited on glassy carbon 83 and Cu x O@NiO–MoO 2 deposited on graphite 84 ) with respect to OER. In addition, the η value for the same current density of our ternary electrocatalyst is similar to that achieved by the Co 56 Mo 21 Cu 23 alloy deposited over carbon steel 48 with respect to HER.…”

Novel mixed heterovalent (Mo/Co)Ox-zerovalent Cu system as bi-functional electrocatalyst for overall water splitting

“…Table 4 introduces the electrocatalytic activity of our fabricated ternary catalyst in contrast to the reported ternary structures of similar components. Our fabricated ternary electrocatalystis of comparable performance to (Cu x Mo x /Co 1−x NPs@RGO deposited on glassy carbon 83 and Cu x O@NiO–MoO 2 deposited on graphite 84 ) with respect to OER. In addition, the η value for the same current density of our ternary electrocatalyst is similar to that achieved by the Co 56 Mo 21 Cu 23 alloy deposited over carbon steel 48 with respect to HER.…”

Novel mixed heterovalent (Mo/Co)Ox-zerovalent Cu system as bi-functional electrocatalyst for overall water splitting

“…Although diverse mixed-metal composites such as NiFe LDH, NiCo LDH, NiCo nanowire arrays, NiMo nanorods, and CuFe have found applications in distinct electrochemical contexts, there exist no admirable research endeavors focused on employing CuFe bimetallic composites as electron engineering platforms to augment the catalytic activity of the grown electrocatalysts towards UOR. [46][47][48][49][50] Even though the catalysts hold the potential to simultaneously execute the catalysis of more than one reaction, ample research endeavors focus only on the design and development of electrocatalysts for a single targeted function, and thus, the true multifunctional potential of the fabricated system is le untapped. Recently, plenteous different studies of these trifunctional electrocatalysts were reported in detail by Balogun and co-workers including catalysts for overall water splitting and diverse battery technologies.…”

“…Although diverse mixed-metal composites such as NiFe LDH, NiCo LDH, NiCo nanowire arrays, NiMo nanorods, and CuFe have found applications in distinct electrochemical contexts, there exist no admirable research endeavors focused on employing CuFe bimetallic composites as electron engineering platforms to augment the catalytic activity of the grown electrocatalysts towards UOR. 46–50…”

Microstructural and electron framework-engineered 3D NiSeP-integrated CuFe composites as trifunctional electrocatalysts for sensing and urea-assisted water-splitting applications

Construction of robust and durable Cu2Se-V2O5 nanosheet electrocatalyst for alkaline oxygen evolution reaction