The 103Rh NMR Spectroscopy and Relaxometry of the Rhodium Formate Paddlewheel Complex

Abstract

The NMR spectroscopy of spin-1/2 nuclei with low gyromagnetic ratio is challenging, due to the low NMR signal strength. Methodology for the rapid acquisition of 103Rh NMR parameters is demonstrated for the case of the rhodium formate "paddlewheel" complex Rh2(HCO2)4. A scheme is described for enhancing the 103Rh signal strength by polarization transfer from 1H nuclei and which also greatly reduces the interference from ringing artifacts, a common hurdle for the direct observation of low-γ nuclei. The 103Rh relaxation time constants T1 and T2 are measured within 20 minutes using 1H-detected experiments. The field-dependence of the 103Rh T1 is measured. The high-field relaxation is dominated by the chemical shift anisotropy (CSA) mechanism. The 103Rh shielding anisotropy is found to be very large: |σ|=9900540\,ppm. This estimate is compared with density functional theory calculations.