ESR linewidths in solution. VIII. Two-component diamagnetic solvents

Abstract

The ESR spectra of dilute vanadyl acetylacetonate were studied in several two‐component solvents as a function of component concentration. A modified Debye equation gives reasonable results for the rotational correlation time τ_ϑ for a number of solvent systems; this equation has the form τ_ϑ= (4π/3) r_⊥³ηκ_⊥/kT, where k is the Boltzmann constant, r_⊥³ a volume which is constant for vanadyl acetylacetonate in all the systems, η is the solvent viscosity, and κ_⊥ is a dimensionless coupling parameter. κ_⊥ is κ_⊥=κ_⊥^(A)x_A +κ_⊥^(B)x_B where κ_⊥^(A) and κ_⊥^(B) are the coupling parameters and x_A and x_B the mole fractions of solvent components A and B, respectively. In ’’ideal’’ cases, these two equations hold quite well. κ_⊥ is independent of temperature, pressure, and viscosity (η), and the excess viscosity (η−η^(A)x_A−η^(B) x_B) is small. η^(A) and η^(B) are the viscosities of pure A and B, respectively. For butanol systems at temperatures decreasing towards room temperature the systems are nonideal and the equations above are not too useful.