摘要
In this work, we report a theoretical exploration of the ground-state electronic structures and molecular vibrational properties of a series of binuclear zirconium complexes in the framework of density functional theory (DFT) employing the B3LYP hybrid functional. The calculated results reveal that the electronic structure of the complex [(η^5-C5Me5)2Zr]2(μ^2, η^2, η^2-N2) is unfavorable for hydrogenation due to the exclusion of side-on dinitrogen in the LUMO+ 1 molecular orbital as compared with the reactant 1 [(η^5-C5Me4H)2Zr]2(μ2,η^2,η^2-N2). Besides, the structural feature of the hypothetical intermediate 1′, [(η^5C5Me4H)2Zr]2(μ2,η^2, η^2-N2)-n2, clearly implies the possibility of further hydrogenation. In addition, the distinguishing of vibrational modes of experimental intermediate 2, [(η^5-C5Me4H)2ZrH]2(μ2,η^2,η^2-N2H2), indicates that the asymmetric stretching of Zr-N and Zr-H leads to dissociation. Moreover, the vibrational intensity of Zr-H is stronger than that of Zr-N. Therefore, it can be predicted that excess hydrogen atmosphere is necessary to ensure the dissociation of Zr-N bonds.
In this work, we report a theoretical exploration of the ground-state electronic structures and molecular vibrational properties of a series of binuclear zirconium complexes in the framework of density functional theory (DFT) employing the B3LYP hybrid functional. The calculated results reveal that the electronic structure of the complex [(η^5-C5Me5)2Zr]2(μ^2, η^2, η^2-N2) is unfavorable for hydrogenation due to the exclusion of side-on dinitrogen in the LUMO+ 1 molecular orbital as compared with the reactant 1 [(η^5-C5Me4H)2Zr]2(μ2,η^2,η^2-N2). Besides, the structural feature of the hypothetical intermediate 1′, [(η^5C5Me4H)2Zr]2(μ2,η^2, η^2-N2)-n2, clearly implies the possibility of further hydrogenation. In addition, the distinguishing of vibrational modes of experimental intermediate 2, [(η^5-C5Me4H)2ZrH]2(μ2,η^2,η^2-N2H2), indicates that the asymmetric stretching of Zr-N and Zr-H leads to dissociation. Moreover, the vibrational intensity of Zr-H is stronger than that of Zr-N. Therefore, it can be predicted that excess hydrogen atmosphere is necessary to ensure the dissociation of Zr-N bonds.
基金
Supported by the National Natural Science Foundation of China (No. 20573114)
MOST Project of 2006DFA43020 and 2007CB815307
