posted on 2013-12-11, 00:00authored byDiego
J. Gavia, May S. Maung, Young-Seok Shon
This
report describes a two-phase synthesis of water-soluble carboxylate-functionalized
alkanethiolate-capped Pd nanoparticles from ω-carboxyl-S-alkanethiosulfate sodium salts. The two-phase methodology
using the thiosulfate ligand passivation protocol allowed a highly
specific control over the surface ligand coverage of these nanoparticles,
which are lost in a one-phase aqueous system because of the base-catalyzed
hydrolysis of thiosulfate to thiolate. Systematic synthetic variations
investigated in this study included the concentration of ω-carboxyl-S-alkanethiosulfate ligand precursors and reducing agent,
NaBH4, and the overall ligand chain length. The resulting
water-soluble Pd nanoparticles were isolated and characterized by
transmission electron microscopy (TEM), thermogravimetric analysis
(TGA), 1H NMR, UV–vis, and FT-IR spectroscopy. Among
different variations, a decrease in the molar equivalent of NaBH4 resulted in a reduction in the surface ligand density while
maintaining a similar particle core size. Additionally, reducing the
chain length of the thiosulfate ligand precursor also led to the formation
of stable nanoparticles with a lower surface coverage. Since the metal
core size of these Pd nanoparticle variations remained quite consistent,
direct correlation studies between ligand properties and catalytic
activities against hydrogenation/isomerization of allyl alcohol could
be performed. Briefly, Pd nanoparticles dissolved in water favored
the hydrogenation of allyl alcohol to 1-propanol whereas Pd nanoparticles
heterogeneously dispersed in chloroform exhibited a rather high selectivity
towards the isomerization product (propanal). The results suggested
that the surrounding ligand environments, such as the ligand structure,
conformation, and surface coverage, were crucial in determining the
overall activity and selectivity of the Pd nanoparticle catalysts.