Arsenic and sulfur nanoparticle synthesis mimicking environmental conditions of submarine shallow-water hydrothermal vents
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Arsenic and sulfur nanoparticle synthesismimicking environmental conditions of submarine shallow-water hydrothermal vents.pdf | 3 MB | Adobe PDF | View/Open |
Authors: | Durán Toro, Vicente Rezwan, Kurosch Bühring, Solveig Maas, Michael |
Publisher: | Fachbereich 04: Produktionstechnik, Maschinenbau & Verfahrenstechnik (FB 04) | Abstract: | Arsenic and sulfur mineralization is a natural phenomenon occurring in hydrothermal systems where parameters like temperature and organic matter (OM) can influence the mobilization of the toxic metalloid in marine environments. In the present study we analyze the influence of temperature and OM (particularly sulfur-containing additives) on As and S precipitation based on the recent discovery of As-rich nanoparticles in the hydrothermal system near the coast of the Greek island Milos. To this end, we experimentally recreate the formation of amorphous colloidal particles rich in As and S via acidification (pH 3-4) of aqueous precursors at various temperatures. At higher temperatures, we observe the formation of monodisperse particles within the first 24 h of the experiment, generating colloidal particles with diameters close to 160 nm. The S:As ratio and particle size of the synthetized particles closely correlates with values for AsxSy particles detected in the hydrothermal system off Milos. Furthermore, organic sulfur containing additives (cysteine and glutathione, GSH) are a key factor in the process of nucleation and growth of amorphous colloidal AsxSy particles and, together with the temperature gradient present in shallow hydrothermal vents, dictate the stabilization of As-bearing nanomaterials in the environment. Based on these findings, we present a simple model that summarizes our new insights into the formation and mobility of colloidal As in aquatic ecosystems. In this context, amorphous AsxSy particles can present harmful effects to micro- and macro-biota not foreseen in bulk As material. |
Keywords: | Arsenic; Biomineralization; Ecotoxicology; Hydrothermal vent; Milos; Nanoparticles; Sulfur | Issue Date: | Jan-2022 | Project: | Programa de Capital Humano Avanzado, BECAS- Chile DFG Emmy Noether Program |
Grant number: | CONICYT, 72160570 Res. Convenio 7359/2015 BU 2606/1-1 to SIB |
Journal/Edited collection: | Journal of environmental sciences (China) | Start page: | 301 | End page: | 312 | Type: | Buch, Monographie | ISSN: | 1001-0742 | Secondary publication: | yes | Document version: | Postprint | DOI: | 10.26092/elib/2811 | URN: | urn:nbn:de:gbv:46-elib77292 | Institution: | Universität Bremen | Faculty: | Fachbereich 04: Produktionstechnik, Maschinenbau & Verfahrenstechnik (FB 04) | Institute: | Fachgebiet 17: Keramische Werkstoffe und Bauteile |
Appears in Collections: | Forschungsdokumente |
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