Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Calcium‐Enhanced Ferric Hydroxide Co‐Precipitation of Arsenic in the Presence of Silicate
This study focuses on the effectiveness of calcium (Ca 2+) improving ferric (hydro)oxides precipitation and its subsequent effects on arsenic co‐precipitation with ferric (hydro)oxides. The effects of Ca 2+ on surface charge characteristics and precipitating behavior, which are respectively represented as zeta (ζ) potential and R PDA, are investigated for ferric (hydro)oxides precipitates. The presence of Ca 2+ increases the ζ potential of ferric (hydro)oxides, and a more significant effect is observed at higher pH conditions. Calcium apparently facilitates ferric (hydro)oxide floc aggregation, increasing the maximum R PDA from 3.19 to 5.27% (in the presence of 3.5 mg/L silicate as silicon). These positive effects contribute to reduce the adverse effects resulting from the presence of silicate and enhance arsenic removal via ferric (hydro)oxides co‐precipitation under different conditions. Furthermore, the effect of Ca 2+ facilitating ferric precipitation (and therefore providing more precipitated solids for arsenic) is predominant in favoring arsenic removal compared with that of increasing surface charge. Calcium plays an important role in arsenic co‐precipitation with ferric (hydro)oxides in the presence of silicate.
Calcium‐Enhanced Ferric Hydroxide Co‐Precipitation of Arsenic in the Presence of Silicate
This study focuses on the effectiveness of calcium (Ca 2+) improving ferric (hydro)oxides precipitation and its subsequent effects on arsenic co‐precipitation with ferric (hydro)oxides. The effects of Ca 2+ on surface charge characteristics and precipitating behavior, which are respectively represented as zeta (ζ) potential and R PDA, are investigated for ferric (hydro)oxides precipitates. The presence of Ca 2+ increases the ζ potential of ferric (hydro)oxides, and a more significant effect is observed at higher pH conditions. Calcium apparently facilitates ferric (hydro)oxide floc aggregation, increasing the maximum R PDA from 3.19 to 5.27% (in the presence of 3.5 mg/L silicate as silicon). These positive effects contribute to reduce the adverse effects resulting from the presence of silicate and enhance arsenic removal via ferric (hydro)oxides co‐precipitation under different conditions. Furthermore, the effect of Ca 2+ facilitating ferric precipitation (and therefore providing more precipitated solids for arsenic) is predominant in favoring arsenic removal compared with that of increasing surface charge. Calcium plays an important role in arsenic co‐precipitation with ferric (hydro)oxides in the presence of silicate.
Calcium‐Enhanced Ferric Hydroxide Co‐Precipitation of Arsenic in the Presence of Silicate
Ruiping, Liu (Autor:in) / Xing, Li (Autor:in) / Shengji, Xia (Autor:in) / Yanling, Yang (Autor:in) / Rongcheng, Wu (Autor:in) / Guibai, Li (Autor:in)
Water Environment Research ; 79 ; 2260-2264
01.10.2007
5 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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