Ion Motion in Tetrafluoroborate Salts. I. NH4BF4 and ND4BF4

Abstract

Proton and fluorine NMR data in NH₄BF₄ and its totally deuterated analog reflect the presence of isotropic and rapid BF₄⁻ tumbling as well as onset of isotropic NH₄⁺ ion motion in the orthorhombic phase. A linewidth transition in the ¹⁹F spin system from 19±1 G² at 133°K to 2.5±0.5 G² at 198°K and ¹⁹F thermal relaxation times measured in ND₄BF₄ from 210° to 478°K yield a span of ¹⁹F correlation times from 3×10⁻⁴ sec (168°K) to 6.4×10⁻¹¹ sec (472°K). The transition to the cubic modification at 472°K decreases the ¹⁹F correlation time to 2.6×10⁻¹² sec (478°K). Above 318°K, fluorine relaxation in NH₄BF₄ is dominated by intraionic dipolar interactions, while below this temperature cross relaxation with protons located on neighboring ammonium ions becomes evident. Deuteration removes this contributor to the ¹⁹F relaxation. The apparent activation energy for BF₄⁻ motion is slightly dependent upon temperature, and increases somewhat with increasing temperature. The pre‐exponential factor associated with ¹⁹F correlation times above 318°K is abnormally small, possibly reflecting a decrease in the effective moment of inertia by mechanical coupling between BF₄⁻ motion and NH₄⁺ motion. Crystallographic measurement of the orthorhombic unit cell parameters from 190° to 296°K shows rapid linear expansion of a and c axes in the range 190° to 260°K, with a marked decrease in the rate of variation of these axis lengths with temperature above 260°K. In the same temperature region a shallow proton T₁ minimum is observed, which may be associated with the modification of NH₄⁺ ion motion by lattice expansion or simply due to cross relaxation with the ¹⁹F spin system. Proton T₁ data also show a shallow plateau at higher temperatures due to interionic dipolar coupling and the BF₄⁻ motion. The x‐ray data suggest the possibility of a subtle crystallographic change at low temperatures. A small linewidth transition is observed for the proton spin system in the range 173°K (4.0±0.1 G²) to 223°K (2.9±0.1 G²) apparently associated with interionic dipolar coupling.