Growth of zinc hexacyanoferrate nanocubes and their potential as heterogeneous catalyst for solvent-free oxidation of benzyl alcohol

“…Benzyl alcohol conversion reaches 100%, when the substrate to oxidant ratio is increased to 1.25. The above result clearly points out that an increase in the TBHP content significantly increases the benzyl alcohol conversion [29]. The selectivity for benzaldehyde is about 98% at this oxidant content.…”

Characterization and catalytic reactivity of mordenite – Investigation of selective oxidation of benzyl alcohol

“…Benzyl alcohol conversion reaches 100%, when the substrate to oxidant ratio is increased to 1.25. The above result clearly points out that an increase in the TBHP content significantly increases the benzyl alcohol conversion [29]. The selectivity for benzaldehyde is about 98% at this oxidant content.…”

Characterization and catalytic reactivity of mordenite – Investigation of selective oxidation of benzyl alcohol

“…In order to get compact and uniform CuHCF nanoparticles, the nucleation rate of CuHCF should be controlled. It is well known that EDTA is a chelator and is capable of controlling the efficient concentration of metal ion in solution [29,30]. So in the present work, EDTA is introduced in electrochemical deposition solution.…”

Electrochemical preparation of copper hexacyanoferrate nanoparticles under the synergic action of EDTA and HAuCl4

“…For instance, MHCF possesses notable electron mediating ability. A variety of MHCFs have been prepared and used for electrochemical sensors [30][31][32][33][34][35]. We previously described a miniaturized amperometric detector coupled to a microfluidic device using CNTs-cobalt hexacyanoferrate (CoHCF) modified graphite electrode; further a microchip electrophoresis-electrochemistry method was proposed [36].…”

An electrochemical sensor for hydrazine and nitrite based on graphene–cobalt hexacyanoferrate nanocomposite: Toward environment and food detection