Solid-State NMR spectra and long, intra-dimer bonding in the pi-[TTF](2)(2+) (TTF = tetrathiafulvalene) dication.

The (13)C chemical-shift tensor principal values for TTF and pi-TTF(2+) (TTF = tetrathiafulvalene) dimer dications have been measured in order to better understand the electronic structure and long intradimer bonding of these TTF-based dimer structures. The structure of pi-TTF(2+) is abnormal due to its two C-C and four S-S ca. 3.4 A intradimer separations, which is less than the sum of the sulfur van der Waals radii, and has a singlet (1)A(1g) electronic ground state. This study of TTF and TTF(2+) was conducted to determine how the NMR chemical-shift tensor principal values change as a function of electronic structure. This study also establishes a better understanding of the interactions that lead to spin-pairing of the monomeric radical units. The density functional theory (DFT) calculated nuclear shielding tensors are correlated with the experimentally determined principal chemical-shift values. The embedded ion method (EIM) was used to investigate the electrostatic lattice potential in TTF(2+). These theoretical methods provide information on the tensor magnitudes and orientations of their tensor principal values with respect to the molecular frame. The experimental chemical-shift principal values agree with the calculated quantum mechanical chemical-shielding principal values, within typical errors commonly seen for this class of molecular system. Relatively weak Wiberg bond orders between the two TTF components of the dimer dication correlate with the long bonds linking the two TTF monomers and substantiate the claim that there is weak multicenter bonding present.