The doi above is for this specific version of this dataset, which is currently the latest. Newer versions may be published in the future. For a link that will always point to the latest version, please use
doi: 10.4121/12927563

Song, Bingnan; Weijma, Jan; van der Weijden, Renata; Buisman, Cees; Tian, Zilin (2021): Dataset associated to publication: "High-rate biological selenate reduction in a sequencing batch reactor for recovery of hexagonal selenium". Version 2. 4TU.ResearchData. dataset. https://doi.org/10.4121/12927563.v2

Dataset

x choose version: version 1 - 2021-01-26

• Environmental Biotechnology
• Other Mineral Resources (excl. Energy Resources)
• Environmental Engineering

biological selenate reduction, ethanol, selenite, selenium recovery, sequencing batch reactor

CC BY 4.0

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by Bingnan Song , Jan Weijma , Renata van der Weijden , Cees Buisman , Zilin Tian

Results belonging to paper "High-rate biological selenate reduction in a sequencing batch reactor for recovery of hexagonal selenium".

Recovery of selenium (Se) from wastewater provides a solution for both securing Se supply and preventing Se pollution. Here, we developed a high-rate process for biological selenate reduction to elemental selenium. Distinctive from other studies, we aimed for a process with selenate as the main biological electron sink, with minimal formation of methane or sulfide. A sequencing batch reactor, fed with an influent containing 120 mgSe L^-1 selenate and ethanol as electron donor and carbon source, was operated for 495 days. The high rates (419 ± 17 mgSe L^-1 day^-1) were recorded between day 446 and day 495 for a hydraulic retention time of 6h. The maximum conversion efficiency of selenate amounted to 96% with a volumetric conversion rate of 444 mgSe L^-1 day^-1, which is 6 times higher than the rates reported in the literature thus far. At the end of the experiment, a highly enriched selenate reducing biomass had developed, with a specific activity of 856±26 mgSe^-1day^-1g_biomass^-1, which was nearly 1000-fold higher than that of the inoculum. No evidence was found for the formation of methane, sulfide, or volatile reduced selenium compounds like dimethyl-selenide or H₂Se, revealing a high selectivity. Ethanol was incompletely oxidized to acetate. The produced elemental selenium partially accumulated in the reactor as pure (≥80% Se of the total mixture of biomass sludge flocs and flaky aggregates, and ~100% of the specific flaky aggregates) selenium black hexagonal needles, with cluster sizes between 20-200 µm. The new process may serve as the basis for a high-rate technology to remove and recover pure selenium from wastewater or process streams with high selectivity.

• 2021-01-26 first online

• 2021-02-04 published, posted

4TU.ResearchData

xlsx csv

High-rate biological selenate reduction in a sequencing batch reactor for recovery of hexagonal selenium

• the Netherlands Enterprise Agency's TKI program
• China Scholarship Council

Environmental Technology, Wageningen University and Research, the Netherlands