Insights into N, P, S multi-doped Mo₂C/C composites as highly efficient hydrogen evolution reaction catalysts

Abstract: N, P, S multi-doped Mo2C/C exhibits highly efficient HER performance, derived from stronger synergistic N, P, S multi-doping coupling effects.

“…2a, the high-resolution C 1s spectrum includes four distinct peaks located at 284.4 eV, 284.75 eV, 285.5 eV, and 286.7 eV, and they can be indexed to C–Mo, C–C/CC, C–N, and CO, respectively. 39,40 The appearance of the C–N peak further confirms the successful doping of the N element in the carbon skeleton. 41 For the O 1s spectrum (Fig.…”

Three-dimensional hierarchical MoO₂/MoC@NC-CC free-standing anode applied in microbial fuel cells

“…2a, the high-resolution C 1s spectrum includes four distinct peaks located at 284.4 eV, 284.75 eV, 285.5 eV, and 286.7 eV, and they can be indexed to C–Mo, C–C/CC, C–N, and CO, respectively. 39,40 The appearance of the C–N peak further confirms the successful doping of the N element in the carbon skeleton. 41 For the O 1s spectrum (Fig.…”

Three-dimensional hierarchical MoO₂/MoC@NC-CC free-standing anode applied in microbial fuel cells

“…However, Mo 2 C nanoparticles have some drawbacks, such as easy agglomeration into large particles, which may result in the slow transport of electrons and protons during HER, fewer available active sites due to larger particles size, and relatively poor conductivity compared to the noble metal nanoparticles, hence leading to poor electrocatalytic activity . Several synthetic and nanostructuring approaches have been developed for an advanced electrocatalyst architecture to achieve the full potential of Mo 2 C as an affordable and efficient electrocatalyst. , These include facile one-step and two-step synthesis methods for highly porous Mo 2 C structures, , nanostructuring, , elemental doping, , and hybrid nanostructures. Despite all these efforts, it still remains a challenge to achieve the desired Mo 2 C nanoarchitecture.…”

“…1 Several synthetic and nanostructuring approaches have been developed for an advanced electrocatalyst architecture to achieve the full potential of Mo 2 C as an affordable and efficient electrocatalyst. 2,3 These include facile one-step and two-step synthesis methods for highly porous Mo 2 C structures, 4,5 nanostructuring, 6,7 elemental doping, 8,9 and hybrid nanostructures. Despite all these efforts, it still remains a challenge to achieve the desired Mo 2 C nanoarchitecture.…”

Molybdenum Carbide-Reduced Graphene Oxide Composites as Electrocatalysts for Hydrogen Evolution

“…19,20 Because S has similar electronegativity to that of a C atom, it tends to change the spin density rather than the charge density after substitution, enriching the electron density of the Mo centers. 21 Moreover, the S edge exhibits a negative hydrogen adsorption energy, 22 which can accelerate the Volmer reaction. Bearing these two merits in mind, we proposed that introduction of S substitution within MoC may be an effective method for optimizing electronic structures to deliver better HER activity.…”

“…Considering that the low electron density of Mo in MoC is mainly due to the excessive carbon in the crystal lattice, substituting part of the C with a suitable anion is likely an effective strategy to enhance the hydrogen adsorption process . It is reported that the HER activity of Mo active sites could be improved when the Mo edge is covered with sulfur (S) atoms. , Because S has similar electronegativity to that of a C atom, it tends to change the spin density rather than the charge density after substitution, enriching the electron density of the Mo centers . Moreover, the S edge exhibits a negative hydrogen adsorption energy, which can accelerate the Volmer reaction.…”

High-Performance MoC Electrocatalyst for Hydrogen Evolution Reaction Enabled by Surface Sulfur Substitution