Roberts Linda C, Hug Stephan J, Ruettimann Thomas, Billah Morsaline, Khan Abdul Wahab, Rahman Mohammad Tariqur
Swiss Federal Institute for Environmental Science and Technology (EAWAG), Uberlandstrasse 133, CH-8600 Dübendorf, Switzerland.
Environ Sci Technol. 2004 Jan 1;38(1):307-15. doi: 10.1021/es0343205.
Arsenic removal by passive treatment, in which naturally present Fe(II) is oxidized by aeration and the forming iron(III) (hydr)oxides precipitate with adsorbed arsenic, is the simplest conceivable water treatment option. However, competing anions and low iron concentrations often require additional iron. Application of Fe(II) instead of the usually applied Fe(III) is shown to be advantageous, as oxidation of Fe(II) by dissolved oxygen causes partial oxidation of As(III) and iron(III) (hydr)oxides formed from Fe(II) have higher sorption capacities. In simulated groundwater (8.2 mM HCO3(-), 2.5 mM Ca2+, 1.6 mM Mg2+, 30 mg/L Si, 3 mg/L P, 500 ppb As(III), or As(V), pH 7.0 +/- 0.1), addition of Fe(II) clearly leads to better As removal than Fe(III). Multiple additions of Fe(II) further improved the removal of As(II). A competitive coprecipitation model that considers As(III) oxidation explains the observed results and allows the estimation of arsenic removal under different conditions. Lowering 500 microg/L As(III) to below 50 microg/L As(tot) in filtered water required > 80 mg/L Fe(III), 50-55 mg/L Fe(II) in one single addition, and 20-25 mg/L in multiple additions. With As(V), 10-12 mg/L Fe(II) and 15-18 mg/L Fe(III) was required. In the absence of Si and P, removal efficiencies for Fe(II) and Fe(III) were similar: 30-40 mg/L was required for As(II), and 2.0-2.5 mg/L was required for As(V). In a field study with 22 tubewells in Bangladesh, passive treatment efficiently removed phosphate, but iron contents were generally too low for efficient arsenic removal.
通过被动处理去除砷是最简单的水处理方案,其中自然存在的亚铁离子通过曝气被氧化,生成的铁(III)(氢)氧化物与吸附的砷一起沉淀。然而,竞争性阴离子和低铁浓度通常需要添加额外的铁。研究表明,应用亚铁离子而非通常使用的铁离子具有优势,因为溶解氧将亚铁离子氧化会导致亚砷酸盐部分氧化,并且由亚铁离子形成的铁(III)(氢)氧化物具有更高的吸附容量。在模拟地下水中(8.2 mM碳酸氢根离子、2.5 mM钙离子、1.6 mM镁离子、30 mg/L硅、3 mg/L磷、500 ppb亚砷酸盐或砷酸盐,pH 7.0±0.1),添加亚铁离子比添加铁离子能更有效地去除砷。多次添加亚铁离子进一步提高了砷的去除率。一个考虑亚砷酸盐氧化的竞争性共沉淀模型解释了观察到的结果,并能估计不同条件下的砷去除情况。将过滤水中500微克/升的亚砷酸盐降低至总砷低于50微克/升,单次添加时需要>80 mg/L铁离子、50 - 55 mg/L亚铁离子,多次添加时需要20 - 25 mg/L亚铁离子。对于砷酸盐,需要10 - 12 mg/L亚铁离子和15 - 18 mg/L铁离子。在没有硅和磷的情况下,亚铁离子和铁离子的去除效率相似:去除亚砷酸盐需要30 - 40 mg/L,去除砷酸盐需要2.0 - 2.5 mg/L。在孟加拉国对22口水井的实地研究中,被动处理有效地去除了磷酸盐,但铁含量通常过低,无法有效去除砷。
