Role of Internal Motions and Molecular Geometry on the NMR Relaxation of Hydrocarbons

Abstract

The role of internal motions and molecular geometry on 1H NMR relaxation times T1,2 in hydrocarbons is investigated using MD (molecular dynamics) simulations of the autocorrelation functions for in tramolecular GR(t) and in termolecular GT(t) 1H-1H dipole-dipole interactions arising from rotational (R) and translational (T) diffusion, respectively. We show that molecules with increased molecular symmetry such as neopentane, benzene, and isooctane show better agreement with traditional hard-sphere models than their corresponding straight-chain n-alkane, and furthermore that spherically-symmetric neopentane agrees well with the Stokes-Einstein theory. The influence of internal motions on the dynamics and T1,2 relaxation of n-alkanes are investigated by simulating rigid n-alkanes and comparing with flexible (i.e. non-rigid) n-alkanes. Internal motions cause the rotational and translational correlation-times τR,T to get significantly shorter and the relaxation times T1,2 to get significantly longer, especially for longer-chain n-alkanes. Site-by-site simulations of 1H's along the chains indicate significant variations in τR,T and T1,2 across the chain, especially for longer-chain n-alkanes. The extent of the stretched (i.e. multi-exponential) decay in the autocorrelation functions GR,T(t) are quantified using inverse Laplace transforms, for both rigid and flexible molecules, and on a site-by-site bases. Comparison of T1,2 measurements with the site-by-site simulations indicate that cross-relaxation (partially) averages-out the variations in τR,T and T1,2 across the chain of long-chain n-alkanes. This work also has implications on the role of nano-pore confinement on the NMR relaxation of fluids in the organic-matter pores of kerogen and bitumen.