The four brown macro-algae studied

The four brown macro-algae studied – P. canaliculata, Laminaria
hyperborea, A. nodosum and F. spiralis – showed to be natural cation
exchangers for heavy metals removal from a petrochemical
wastewater. Functional groups present on the surface of the
biomass, such as carboxylic and sulfonic groups, are responsible
by their cation exchanger properties. The binding of metal ions
(Zn, Ni, Cu and Ca) take place by the release of light metals (Na,
K and Mg), initially bound to the functional groups. Langmuir
multicomponent isotherm was able to predict the ion exchange
equilibrium for the four brown macro-algae. A mass transfer
model, considering the intraparticle ion diffusion as a limiting step,
was able to fit the concentration profile of the metal bound species
at the liquid and solid phase. L. hyperborea showed a higher affinity
for Zn, Ni and Cu species than the other brown algae. FTIR, potentiometric
titration and biomass digestion results were able toidentify and quantify the functional groups present on the L. hyperborea.
In a packed bed column, Zn, Ni and Ca break through faster
than Cu, in agreement with the affinity constants to the binding
sites. The treatment strategy defined for the petrochemical
wastewater includes two consecutive packed bed columns (in series),
where copper ions are mainly separated in the first column
and zinc and nickel ions are retained in the second column. The
service cycle in the first column, concerning copper removal was
1384 BV (7.2 BV/h). For the second column, the service capacity
was of 163 BV (7.3 BV/h), concerning zinc and nickel removal. 1 g
of biomass was able to treat near 3.1 and 0.4 liters of the petrochemical
wastewater, concerning the removal of copper ions in
the first column and zinc and nickel in the second one. A mass
transfer model was able to predict successfully the ion exchange
process during the saturation step in the packed bed column.
To achieve a desorption efficiency of 90% using a 1.2% HCl solution
at a flow rate of 3.0 BV/h, it was necessary only 10 BV and 6 BV
of eluent, for the first and second columns, respectively. The pH
breakthrough profile can be used as an indicator of transition metals
elution curves. The ratio of Vtreated/Vdesorption was 135 and 28 for
the first and second column. It is necessary 150 and 90 g HCl per
liter of the natural resin to achieve 90% conversion of the alga to
H+ form, for the first and second column experiments, respectively