Activation of Ni Particles into Single Ni–N Atoms for Efficient Electrochemical Reduction of CO₂

Abstract: within acceptable limits are needed. Among the many possible solutions, electrochemical CO 2 reduction (ECR) offers a potentially sustainable approach not only for depressing CO 2 concentration but also converting it into fuels and commodity chemicals. [2] Unfortunately, the CO chemical bond in CO 2 (≈806 kJ mol −1 ) is thermodynamically very stable and its conversion is an uphill energy process with a high activation barrier. Moreover, during electrochemical reduction of CO 2 , the hydrogen evolution reactio… Show more

“…2d and S18 †); this is likely due to the dense graphitic carbon layer that protects the NPs. 55,58,59 Upon closer inspection of the CNTs, a considerable amount of single atom nickel species are found distributed throughout the CNTs (Fig. 2e).…”

“…53,54 Moreover, residual nickel nanoparticles in the carbon matrix can potentially act as a source for the formation of more single atom nickel sites during catalyst preparation if extra polymer and the second thermal treatment was adopted. 55,56 In addition to residual NPs, high-angle annular dark-eld (HAADF) STEM images and EDXS elemental maps clearly conrm the presence of single Ni atom sites in all three carbons ( Fig. S12-S16 † and Fig.…”

A metal–organic framework/polymer derived catalyst containing single-atom nickel species for electrocatalysis

“…2d and S18 †); this is likely due to the dense graphitic carbon layer that protects the NPs. 55,58,59 Upon closer inspection of the CNTs, a considerable amount of single atom nickel species are found distributed throughout the CNTs (Fig. 2e).…”

“…53,54 Moreover, residual nickel nanoparticles in the carbon matrix can potentially act as a source for the formation of more single atom nickel sites during catalyst preparation if extra polymer and the second thermal treatment was adopted. 55,56 In addition to residual NPs, high-angle annular dark-eld (HAADF) STEM images and EDXS elemental maps clearly conrm the presence of single Ni atom sites in all three carbons ( Fig. S12-S16 † and Fig.…”

A metal–organic framework/polymer derived catalyst containing single-atom nickel species for electrocatalysis

“…Very recently, single Ni atoms with a NiN 3 moiety were prepared via the transformation of Ni particles confined in N‐doped carbon nanotubes upon a one‐step pyrolysis strategy. [ 89 ] The single Ni catalysts displayed low onset potential of −0.4 V and a high EF over 90% with an overpotential of 690 mV. According to DFT calculations, a lower free energy for the formation of *COOH was required on the Ni@N 3 (pyrrolic) sites compared with Ni@N 4 sites and thus was reasonable for the excellent ECR activity.…”

Recent Advances in Atomic‐Level Engineering of Nanostructured Catalysts for Electrochemical CO₂ Reduction

“…As one of the non-noble metal SAs, Ni SAs are the most widely investigated SAs for catalyzing the CO 2 reduction, but they are typically combined with the substrates to generate a stable format. [155] Carbonaceous materials are the commonly used substrates, including graphene sheets, [156][157][158][159] carbon nanotubes, [160,161] and porous carbon frameworks. [162][163][164][165] For instance, the dispersion of Ni SAs into NG (Ni-NG) sheets, without the involvement of Ni nanoparticles, was reported to serve as the active sites for catalyzing CO 2 reduction to carbon monoxide (CO) ( Figure 6).…”

“…Ni SAs were also obtained from Ni particles, and previously, these particles served as the catalysts for the growth of carbon nanotubes. [160] Ni SAs were postulated to be existing in the format of the NiN 3 moiety, surrounded by a porous N-doped carbon sheath. The electrocatalyst can appropriately facilitate the highly efficient electroreduction of CO 2 at a very low potential to yield CO, presenting a CO Faradaic efficiency (FE) of above 90%, high turnover frequency, and metal mass activity.…”

Emerging Metal Single Atoms in Electrocatalysts and Batteries