The speciation and particle-water interactions of Ni were investigated in three estuaries
with contrasting pollution levels, hydrodynamics and geochemical characteristics. Samples
of water and sediments were collected seasonally from the Tamar, Tweed and Mersey
Estuaries. The chemical speciation of dissolved Ni was determined by adsorptive cathodic
stripping voltammetry (ACSV), and the sorptive behaviour of Ni was studied under
simulated estuarine conditions using " Ni coupled to liquid scintillation counting.
A relatively high particle reactivity was observed only in the Tamar Estuary, where ACSV-non
labile Ni was removed in the low salinity region, followed by addition of ACSV-labile
Ni in the mid-estuarine region. The largely conservative behaviour of dissolved Ni in the
Tweed Estuary was attributed to the combination of rapid flushing and low suspended
particles concentration. In the Mersey Estuary, dissolved Ni (and Co, Zn, Cd and Pb) often
showed positive deviations from conservative behaviour, which were attributed to
anthropogenic and/or geochemical inputs. The fraction of ACSV-non labile Ni behaved
differently in the three estuaries, with a sharp decrease from 90 to 30% from freshwater to
seawater in the Tamar, scatter between 30 and 70% in the Tweed, and relatively constant
values of 50-70% in the Mersey. These differences are interpreted within the context of
different hydrodynamics and geochemistry of the three estuaries. Speciation modelling
showed that between 30 and 70% of dissolved Ni in the Tweed, and between 50 and 70%
in the Mersey, was bound to a class of strong ligands (log K'NIL = 19.0 ± 0.4 and 18.7 ±
0.5, respectively), which were saturated by the ambient concentrations of Ni throughout
the estuaries, suggesting that the ligands are highly specific towards Ni.
Irradiation of riverwater samples with UV light (believed to remove dissolved organic
matter) significantly enhanced Ni uptake onto estuarine suspended particulate matter, with
an increase in the 63Ni distribution coefficients (Kds) of up to 10 fold. Conversely, the
addition of synthetic humic acids to UV-treated riverwater decreased significantly the 63Ni
Kds. Complexation of Ni by dissolved natural ligands also affected the progression of
sorptive reactions, with a system response time (i.e. the time required to achieve 63% of
the sorptive equilibrium) between 1.6 and 8.9 hours.
The results from this study suggest that the low particle reactivity generally exhibited by
Ni during estuarine mixing is due to its ability to complex strongly with dissolved natural
ligands (truly dissolved organic or colloidal organic/inorganic), and therefore resist
adsorption onto particles.
Date of Award | 2000 |
---|
Original language | English |
---|
Awarding Institution | |
---|
COMPLEXATION AND PARTICLE-WATER INTERACTIONS OF NICKEL IN ESTUARIES
MARTINO, M. (Author). 2000
Student thesis: PhD