Issue 4, 1994

Speciation, structural characteristics and proton dynamics in the systems NH4NO3· 1.5H2O and NH4NO3· 1.5H2O–(HNO3, NH4F, NH3)–H2O at 50 °C

Abstract

In order to obtain a good basis for exploring metal-ion complex formation in molten NH4NO3· 1.5H2O, some fundamental characteristics of the pure hydrous melt and a number of compositions in the NH4NO3· 1.5H2O–(HNO3, NH4F, NH3)–H2O system, have been investigated at 50 °C. Several aspects have been taken into consideration, e.g. thermodynamics of solvent autoprotolysis and HF formation, dynamics of proton exchange and structural properties. The acid dissociation constant of NH+4, Ka, and the equilibrium constant for formation of HF, KHF, were obtained from potentiometric measurements; Ka=(2.2 ± 0.2)× 10–9(mol kg–1)2 and KHF= 2160 ± 40 (mol kg–1)–1. Results from 19F NMR spectroscopy indicate that unprotonated fluoride, F, probably exists as an H3NH+⋯F ion pair in the solvent. The change in the 19F chemical shift with increasing HNO3 content in (NH4NO3–NH4F–HNO3)· 1.5H2O verifies the conclusion from potentiometric data that HF is the only proteonated fluoride species present. Raman spectroscopy and 14N NMR experiments give clear evidence for an increased tendency to NH+4⋯NO3 ion-pair formation with decreasing water content in the systems NH4NO3–H2O. However, no loss of degeneracy of the internal ν3 and ν4 nitrate bands at 1380 and 718 cm–1, respectively, was observed. The D3h symmetry of NO3 seems to be preserved in the NH4NO3· 1.5H2O melt. Results from Raman scattering, 1H NMR and 14N NMR experiments show significant changes in the spectra upon acidification with HNO3. These observations suggest an increase in hydrogen-bonding ability with increasing acidity. Results from large-angle X-ray scattering experiments on NH4NO3· 1.5H2O cannot be explained by a model comprising only interactions between water molecules and ions. A residual contribution to the overall radial electron density distribution at 1.8 Å is tentatively assigned to remarkably short N(NH4)–O(NO3) distances. 1H NMR spectroscopy shows a strong retardation of the proton exchange between NH+4 and H2O in the acidic region. The rate constant, kH, for the proton-exchange step H3N ·HOH(OH2)s–1+ H2O → H3N ·(OH2)s+HOH, is estimated at (4.3 ± 1.5)× 107 s–1.

Article information

Article type
Paper

J. Chem. Soc., Faraday Trans., 1994,90, 559-570

Speciation, structural characteristics and proton dynamics in the systems NH4NO3· 1.5H2O and NH4NO3· 1.5H2O–(HNO3, NH4F, NH3)–H2O at 50 °C

L. A. Bengtsson, F. Frostemark and B. Holmberg, J. Chem. Soc., Faraday Trans., 1994, 90, 559 DOI: 10.1039/FT9949000559

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