Effect of Nanoparticle Ligands on 4-Nitrophenol Reduction: Reaction Rate, Induction Time, and Ligand Desorption

Abstract: Ligands are the quintessential synthesis tool in the preparation of colloidal metal catalysts, allowing for the rational design of nanostructured surfaces with high activity and selectivity. These same agents can, however, strongly influence the catalytic performance of metal nanostructures in aqueous media. In this regard, the current literature describing the influence of ligands on the model catalytic reaction that sees 4-nitrophenol reduced to 4-aminophenol by borohydride is highly fragmented in that the u… Show more

“…For all Pd/SiO 2 -TiO 2 catalytic membranes, the only product PAP is obtained (data not shown here), in line with the reported results [2,12,13,19]. In each case, the conversion increases rapidly in the early stage of reaction and then gradually becomes stable, possibly because that NaBH 4 is gradually hydrolysed as the reaction goes on, resulting in the decrease of the reaction rate [42]. Interestingly, with the increase of TiCl 3 solution dosage, the catalytic efficiency first rises, reaches the highest at a dosage of 0.2 mL and reduces.…”

Flexible hierarchical Pd/SiO₂-TiO₂ nanofibrous catalytic membrane for complete and continuous reduction of p-nitrophenol

“…For all Pd/SiO 2 -TiO 2 catalytic membranes, the only product PAP is obtained (data not shown here), in line with the reported results [2,12,13,19]. In each case, the conversion increases rapidly in the early stage of reaction and then gradually becomes stable, possibly because that NaBH 4 is gradually hydrolysed as the reaction goes on, resulting in the decrease of the reaction rate [42]. Interestingly, with the increase of TiCl 3 solution dosage, the catalytic efficiency first rises, reaches the highest at a dosage of 0.2 mL and reduces.…”

Flexible hierarchical Pd/SiO₂-TiO₂ nanofibrous catalytic membrane for complete and continuous reduction of p-nitrophenol

“…If a capping agent is not suitable, it can also act as a "poison" for the nanocatalyst and limit the accessibility of active sites. 67 To date, most efforts have been limited to exploring the roles of molecular ligands in controlling the size and the facet of nanoparticles during nanoparticle synthetic steps. Stabilizers used for the development of nanocatalysts include dendrimers, surfactants, polymers, ionic liquids, and organofluorous ligands.…”

Organoselenium ligands for heterogeneous and nanocatalytic systems: development and applications

“…Such transformations may be reasoned by the Au NCs dissolution followed by reshaping caused by infused chloride ions into the carbon shell 21 . In order to evaluate the catalytic performance of such clustered Au NCs of Au@ h ‐Carbon , we performed the reduction of 2‐amino‐4‐nitrophenol (NP; 1.2 mM) by Au@ h ‐Carbon catalyst 22 . The real‐time monitoring of the reduction process in every 10 min interval for the next 1 h revealed the gradual discoloration of the deep yellow solution with successive lowering of UV‐vis absorbance spectra at 443 nm and evolution of new peak at 323 nm indicating the formation of 2,4‐diaminophenol (AP) (Figure 3).…”

Yolk@Shell Nanoreactors Carrying a Cluster of Metal Nanocrystals Stabilized Inside the Hollow Carbon Shell