NMR studies of phosphorus chalcogenide–copper iodide coordination compounds

Abstract

The local structures of the new phosphorus chalcogenide – copper iodide coordination compounds (CuI)P₄Se₄, (CuI)₂P₈Se₃, (CuI)₃P₄Se₄, and (CuI)₃P₄S₄ are investigated using comprehensive ⁶³Cu, ⁶⁵Cu, and ³¹P magic angle spinning NMR techniques. Peak assignments are proposed on the basis of homo- and heteronuclear indirect spin–spin interactions, available from lineshape analysis and/or two-dimensional correlation spectroscopy. In particular, the ³¹P-^63,65Cu scalar coupling constants have been extracted from detailed lineshape simulations of the ³¹P resonances associated with the Cu-bonded P atoms. In addition, the RN^ν _n pulse symmetry concept of Levitt and coworkers has been utilized for total through-bond correlation spectroscopy (TOBSY) of directly-bonded phosphorus species. The resonance assignments obtained facilitate a discussion of the ³¹P and ^63,65Cu NMR Hamiltonian parameters in terms of the detailed local atomic environments. Analysis of the limited data set available for this group of closely related compounds offers the following conclusions: (1) bonding of a special phosphorus site in a given P₄X_n (X=S, Se) molecule to Cu⁺ ions shifts the corresponding ³¹P NMR signal upfield by about 50 ppm relative to the uncomplexed molecule, (2) the magnitude of the corresponding scalar ³¹P-^63,65Cu spin–spin coupling constant tends to decrease with increasing Cu–P distance, and (3) the ^63,65Cu nuclear electric quadrupolar coupling constants appear to be weakly correlated with the shear strain parameter specifying the degree of local distortion present in the four-coordinated [CuI₂P₂] and [CuI₃P] environments. Overall, the results illustrate the power and potential of advanced solid state NMR methodology to provide useful structural information in this class of materials.