The work in this thesis is concerned with the Green Rusts, which are bluegreen
metastable Fe(II) - Fe(III) hydroxy compounds incorporating anions
such as SO42-, Cl- or CO3-. These Green Rust compounds (or Fe-GR compounds
to distinguish them from the aluminium Green Rusts (Al-GRs) which
are isostructural Fe(II) - Al(III) hydroxy compounds) can be produced in
a consistent fashion from Fe(II) solutions by the method of induced hydrolysis
using Fe(III) gel at pH 7 and under anoxic conditions. A series of
sulphate and chloride Fe-GR samples were synthesised, and characterised
primarily by the analytical techniques of M8ssbauer spectroscopy, X-Ray
diffractometry, infra-red spectroscopy, and vacuum microbalance to measure
surface area using the BET N2 adsorption method.
For comparison, a few samples of the analogous Al-GR compounds were also
synthesised and characterised by the analytical techniques mentioned above.
The results in this thesis showed that the systems producing the Fe-GR compounds
were of a highly complex nature, and that the amount of precipitate
formed depended crucially on the starting conditions. For the 0.1 M FeSO4
system, the GR formed was almost always accompanied by a goethite phase
while, for the 0.1 M FeC12 system, pure GR material was only formed at
initial Fe(II) - Fe(III) ratios (IFFRs) greater than 6. Any-differences
between__the, sulphate and chloride Fe-GRs can. be attributed to the difference
in anion-type. X-Ray diffraction in conjunction with electron microscopy
and surface area measurements confirm-that the Fe-GRs have a pyroaurite
crystal structure, with brucite-like layers formed by a matrix of Fe2+ and
Fe 3+ cations and each layer bridged to the other by anions. As far as
Messbauer spectroscopy is concerned, the most important diagnostic parameter
is the quadrupole splitting (QS) of the Fe(II) doublet measured at 77K for
the wet, fresh precipitate (i. e. frozen material). For sul phate Fe-GRs
derived from 0.1 M FeSO4 the mean QS is 2.93 ± 0.05 mms-', while for the
chloride Fe-GRs derived from 0.1 M FeC12 the mean QS is 2.80 ± 0.05 mms-1.
Surface areas for the sulphate Fe-GRs are in the range 40-65 m2. g-1.
The products of oxidation and ageing for the Fe-GRs indicate several transformation
pathways, especially for the chloride Fe-GRs. Sulphate Fe-GRs
converted to goethite on oxidation under both wet and dry conditions, while
the chloride Fe-GRs converted to akaganeite on dry oxidation, and to lepidocrocite
on wet oxidation. Under both wet and dry anoxic conditions, the
chloride Fe-GRs converted to magnetite. In the case of the sulphate Fe-GRs,
there was a suggestion that, under the right wet anoxic conditions, the
material probably transformed into magnetite. These facts clearly demonstrate
that the Fe-GRs are intermediaries in the thermodynamic transformation
of Fe in the II oxidation state to Fe in the III oxidation state.
Date of Award | 1987 |
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Original language | English |
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Awarding Institution | |
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THE CHARACTERISTICS OF SYNTHETIC AND NATURAL HYDROUS IRON OXIDES IN AQUEOUS ENVIRONMENTS
Man, V. (Author). 1987
Student thesis: PhD