This paper presents the vacuum structures of aquacopper(II) bis(amino acid) complexes with glycine, sarcosine, N,N-dimethylglycine, and N-tert-butyl-N-methylglycine estimated using the B3LYP method. The differences between the B3LYP vacuum structures and experimental crystal structures suggested considerable influence of crystal lattice packing effects on the changes in the complexes' geometries. A previously developed molecular mechanics force field for modeling anhydrous copper(II) amino acidates was reoptimized to simulate these changes and predict the properties of both trans and cis anhydrous and aqua copper(II) amino acid complexes. The modeling included experimental molecular and crystal structures of 13 anhydrous and 10 aqua copper(II) amino acidates with the same atom types (Cu(II), C, H, N, and O) but various copper(II) coordination polyhedron geometries, crystal symmetries, and intermolecular interactions. The empirical parameters of the selected potential energy functions were optimized on the B3LYP vacuum copper(II) coordination geometries of three anhydrous copper(II) amino acidates and on experimental crystalline internal coordinates and unit cell dimensions of six anhydrous and six aqua copper(II) amino acid complexes. The respective equilibrium structures were calculated in vacuo and in simulated crystalline environment. The efficacy of the final force field, FFW, was examined. The total root-mean-square deviations between the experimental and theoretical crystal values were 0.018 A in the bond lengths, 2.2 degrees in the valence angles, 5.5 degrees in the torsion angles, and 0.395 A in the unit cell lengths. FFW reproduced the unit cell volumes in the range from -8.1 to 9.6%. The means of Cu to axial water oxygen distances were 2.4 +/- 0.1 A (experiment) and 2.6 +/- 0.1 A (FFW). This paper describes the ability of the molecular mechanics model and FFW force field to simulate the flexibility of the metal coordination polyhedron. The new force field proved effective in predicting the most stable molecular conformation of copper(II) amino acidato systems in vacuo.
This paper presents geometries of copper(II) chelates with l-alanine, l-leucine, and l-N,N-dimethylvaline optimized by the hybrid density functional method B3LYP. According to the molecular quantum mechanics results, a square-planar copper(II) coordination geometry is electronically favored in vacuo. Deviations from the planar configuration observed in the crystal state should be attributed to sterical intramolecular and/or intermolecular effects. This paper proposes a new molecular mechanics model for tetracoordinated copper(II) amino acidates to investigate these effects in detail. The empirical parameter set for the selected potential energy functions was optimized both with respect to the X-ray crystal structures (internal coordinates and unit cell constants) and with respect to the quantum mechanically derived valence angles around copper. To test this newly developed force field (FF), the equilibrium geometries of 10 molecules are predicted in vacuo and in approximate crystalline surrounding. The results were compared with their ab initio and experimental crystal structures, respectively. The unit cell volumes were reproduced in a range from −7.0% to 2.1%. The total root-mean-square deviations between the experimental and FF in crystal internal coordinates were 0.017 Å in the bond lengths, 2.2° in the valence angles, and 3.6° in the torsion angles. The force field is capable of reproducing the changes in the chelate rings' torsion angles caused by the crystal packing forces and successfully explains the nonplanarity of Cu(II) amino acid complexes in their crystal structures.
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