Study on bioaccumulation and biosorption of mercury by living marine macroalgae: Prospecting for a new remediation biotechnology applied to saline waters

[Display omitted] •The removal of Hg from water by living algae was investigated at realistic levels.•All seaweeds showed huge accumulation capabilities, reaching up to 209μgHgg−1.•U. lactuca achieved 99% of removal, leading to Hg levels in seawater below 1μgL−1.•Bioaccumulation was more advantageou...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2015-12, Vol.281, p.759-770
Main Authors: Henriques, Bruno, Rocha, Luciana S., Lopes, Cláudia B., Figueira, Paula, Monteiro, Rui J.R., Duarte, A.C., Pardal, M.A., Pereira, E.
Format: Article
Language:English
Subjects:
Bioaccumulation
Biosorption
Kinetic modeling
Marine macroalgae
Mercury
Organo-metallic forms
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Summary:[Display omitted] •The removal of Hg from water by living algae was investigated at realistic levels.•All seaweeds showed huge accumulation capabilities, reaching up to 209μgHgg−1.•U. lactuca achieved 99% of removal, leading to Hg levels in seawater below 1μgL−1.•Bioaccumulation was more advantageous than biosorption in terms of efficiency.•The volatilization of Hg or its conversion to organometallic forms was negligible. This study aimed to assess and explore the bioaccumulation capabilities of three different macroalgae species, Ulva lactuca (green), Gracilaria gracilis (red) and Fucus vesiculosus (brown), very common on temperate coasts and estuaries, for the removal of mercury (Hg) from contaminated waters (with high salinity), using environmentally realistic concentrations of metal (10–100μgL−1). Levels of Hg accumulated by all seaweeds ranged between 20.8 and 208μgg−1, corresponding to bioconcentration factors of c.a. 2000. A comparative evaluation of bioaccumulation (living biomass) and biosorption (dried biomass) was performed for U. lactuca, which had displayed the best performance in accumulating Hg. The removal conducted by the living seaweed (mmacroalgae/Vsolution≈500mgL−1), although slower, was more promising since all Hg levels were reduced by about 99%, fulfilling the European criteria for drinking water quality. Pseudo-second-order and Elovich models described quite well the experimental data, assuming a process essentially of chemical nature. Determination of total Hg content in algal biomass over time, allowed to confirm and to follow the uptake of this metal by the living organism. Volatilization of Hg or its conversion to organo-metallic forms (0.02–0.05%) was negligible during the decontamination process. Overall, the results are a contribution for the development of an efficient and cost-effective water remediation biotechnology, based on the use of living macroalgae to promote the removal of Hg.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2015.07.013