posted on 2014-11-07, 00:00authored byTian Yi Ma, Shi Zhang Qiao
Integrating
multiple functions into one host for improved catalytic
performance is challenging and promising for both catalysis and material
science. Herein a new acid–base bifunctional periodic mesoporous
titanium phosphonate hybrid material is synthesized by a facile one-pot
hydrothermal method, using alendronate sodium trihydrate as a coupling
molecule. The new material possesses highly periodic mesopores with
a large specific surface area of 540 m2 g–1 and pore volume of 0.43 cm3 g–1, favoring
the smooth mass transport of reactants and products during the catalytic
reaction. It also has an organic–inorganic hybrid framework
with homogeneously incorporated phosphonate groups, in which a large
number of accessible acidic P–OH and basic −NH2 sites can, respectively, activate aziridine and CO2,
synergistically leading to the high conversion (>99%), yield (98%),
and regioselectivity (98:2) for the CO2 cycloaddition reaction.
The catalytic activity is better than that of the scarcely reported
heterogeneous catalysts for aziridine and CO2 cycloaddition
and even comparable to that of the state-of-the-art homogeneous ones.
Moreover, being superior to the other catalysts, the metal phosphonate
materials can be easily separated and reused repeatedly without activity
loss, and no hazardous halogen ions, organic solvents, or cocatalysts
are needed for the catalytic process. In comparison with previously
reported multifunctional catalysts synthesized by complicated multistep
fabrications, the facile one-pot preparation of mesoporous metal phosphonates
with dual active sites makes it more practical for high-performance
heterogeneous catalysis.