On the Coordination Role of Pyridyl-Nitrogen in the Structural Chemistry of Pyridyl-Substituted Dithiocarbamate Ligands

Mechanochromic and Solvent-Induced Luminescence of a Supramolecular Pt(II)-Bipyridine Complex with Di(4-pyridylmethyl)aminedithiocarbamate

[Pt(bpy)(DPMACS2)]2Cl2•3H2O (1•3H2O) (bpy = 2,2'-bipyridine, DPMACS2 = di(4-pyridylmethyl)aminedithiocarbamate) was synthesized and characterized by X-ray diffraction studies, and its crystal structure displayed intermolecular Pt(II)···Pt(II) contacts of 3.471 and 5.065 Å. Upon excitation, 1•3H2O showed broad luminescence at 538 nm, which was red-shifted and enhanced to 560 nm while cooling to 77 K. To this end, the B3LYP/LanL2DZ calculation results were performed to clearly explain their excited-state origin. Moreover, complex 1•3H2O displayed a dramatic mechanochromic shift from 538 to 608 nm while grinding, and the above red-shift was also observed while exposed to air within 1 day, suggestive of the simultaneous mechanochromic and solvent-induced luminescence. It is noted that the luminescence almost reverted to the original luminescence at 535-542 nm upon immersion in various solvents for the ground samples of complex 1•3H2O. In addition, the luminescence for the acetone-immersed ground samples returned to 608 nm in 1 min. The possible interactions between halogenated solvents and the free pyridyl groups in DPMACS2, which were not expected for acetone, have been proposed to be responsible for such a dramatic difference in this study.

The Coordination Chemistry of Imidomethanedithiolate Di-anions: A Structural Comparison with Their Dithiocarbamate Analogs

A review of the coordination chemistry along with the structural features of heavy element complexes of dithiocarbimate di-anions in the form of [(R)C=NCS2]2− for R = CN, alkyl, and aryl are described. This class of compound is far less studied compared with the well-explored dithiocarbamate mono-anions formulated as [R(R’)NCS2]− for R/R’ = H, alkyl, and aryl. The coordination chemistry of dithiocarbimate di-anions is dominated by a S,S-chelating mode; rare examples of alternative modes of coordination are evident. When comparisons are available, the structural motifs adopted by metal dithiocarbimate complexes match those found for their dithiocarbamate analogs, with only small, non-systematic variations in the M–S bond lengths.

Dithiocarbamate Complexes of Platinum Group Metals: Structural Aspects and Applications

The incorporation of dithiocarbamate ligands in the preparation of metal complexes is largely prompted by the versatility of this molecule. Fascinating coordination chemistry can be obtained from the study of such metal complexes ranging from their preparation, the solid-state properties, solution behavior as well as their applications as bioactive materials and luminescent compounds, to name a few. In this overview, the dithiocarbamate complexes of platinum-group elements form the focus of the discussion. The structural aspects of these complexes will be discussed based upon the intriguing findings obtained from their solid- (crystallographic) and solution-state (NMR) studies. At the end of this review, the applications of platinum-group metal complexes will be discussed.