Controlling
the nanostructures and chemical compositions of the
electrochemical nanocatalysts has been recognized as two prominent
means to kinetically promote the electrocatalytic performance. Herein,
we report a general “dual”-template synthesis methodology
for the formation of multimetallic hollow mesoporous nanospheres (HMSs)
with an adjustable interior hollow cavity and cylindrically opened
mesoporous shell as a highly efficient electrocatalyst for ethanol
oxidation reaction. Three-dimensional trimetallic PdAgCu HMSs were
synthesized via in situ coreduction of Pd, Ag, and Cu precursors on
“dual”-template structural directing surfactant of dioctadecyldimethylammonium
chloride in optimal synthesis conditions. Due to synergistic advantages
on hollow mesoporous nanostructures and multimetallic compositions,
the resultant PdAgCu HMSs exhibited significantly enhanced electrocatalytic
performance toward ethanol oxidation reaction with a mass activity
of 5.13 A mgPd–1 at a scan rate of 50
mV s–1 and operation stability (retained 1.09 A
mgpd–1 after the electrocatalysis). The
“dual”-template route will open a new avenue to rationally
design multimetallic HMSs with controlled functions for broad applications.
Mesoporous colloidal nanospheres with tailorable asymmetric nanostructures and multimetallic elemental compositions are building blocks in next-generation heterogeneous catalysts. Introducing structural asymmetry into metallic mesoporous frameworks has never been demonstrated, but it would be beneficial because the asymmetry enables the spatial control of catalytic interfaces, facilitates the electron/mass transfer and assists in the removal of poisonous intermediates. Herein, we describe a simple bottom-up strategy to generate uniform sub-100 nm multimetallic asymmetric bowl-shaped mesoporous nanospheres (BMSs). This method uses a surfactant-directed "dual"-template to control the kinetics of metal reduction on the surface of a vesicle, forming mesoporous metal islands on its surface whose spherical cone angle can be precisely controlled. The asymmetric BMS mesostructures with different spherical cone angles (structural asymmetries) and elemental compositions are demonstrated. The high surface area and asymmetric nature of the metal surfaces are shown to enhance catalytic performance in the alcohol oxidation reactions. The findings described here offer novel and interesting opportunities for rational design and synthesis of hierarchically asymmetric nanostructures with desired functions for a wide range of applications.
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