Arsenic removal from water/wastewater using adsorbents—A critical review

https://dr.ntu.edu.sg/bitstream/10356/96770/1/30.%20Application%20of%20Layered%20Double%20Hydroxides%20for%20Removal%20of%20Oxyanions.pdf

Application of layered double hydroxides for removal of oxyanions: A review

Über die Adsorption in Lösungen

Among various water purification and recycling technologies, adsorption is a fast, inexpensive and universal method. The development of low-cost adsorbents has led to the rapid growth of research interests in this field. The present protocol describes salient features of adsorption and details experimental methodologies for the development and characterization of low-cost adsorbents, water treatment and recycling using adsorption technology including batch processes and column operations. The protocol describes the development of inexpensive adsorbents from waste materials, which takes only 1-2 days, and an adsorption process taking 15-120 min for the removal of pollutants. The applications of batch and column processes are discussed, along with suggestions to make this technology more popular and applicable.

/pdf/advances-in-water-treatment-by-adsorption-technology-jevlg7pb9w.pdf

Advances in water treatment by adsorption technology

Mechanisms of metal sorption by biochars: Biochar characteristics and modifications

Arsenic adsorption was carried out on simple materials such as goethite and amorphous iron hydroxide, and more complex matrices such as clay pillared with titanium(IV), iron(III), and aluminum(III). These matrices were synthesized from a bentonite whose montmorillonitic fraction was pillared according to optimized parameters. These sorbents were characterized by various methods: XRD, FTIR, BET, DTA/TGA, surface acidity, and zetametry. Elimination of arsenite and arsenate as a function of pH was studied. Arsenate elimination was favored at acidic pH, whereas optimal arsenite elimination was obtained at 4<pH<9. For pH values above 10, the pillared clays were damaged and elimination decreased. Equilibrium time and adsorption isotherms were also determined for arsenite and arsenate at each matrix auto-equilibrium pH. Amorphous iron hydroxide had the highest adsorption capacities both towards arsenate and arsenite. Adsorption capacities of goethite and iron- and titanium-pillared clays toward arsenate were similar, but those toward arsenite were different. Desorption experiments from the various matrices were carried out. Iron- and titanium-pillared clays showed a desorption capacity above 95% and around 40% respectively, but no desorption rate could be obtained for iron (hydr)oxides as they were damaged during the process.

Arsenic adsorption onto pillared clays and iron oxides.

Arsenite oxidation and arsenate determination by the molybdene blue method

As(V) retention and As(III) simultaneous oxidation and removal on a MnO2-loaded polystyrene resin.

https://hal-univ-tln.archives-ouvertes.fr/hal-01096845/document

Véronique Lenoble

Papers

Arsenic adsorption onto pillared clays and iron oxides.

Arsenite oxidation and arsenate determination by the molybdene blue method

As(V) retention and As(III) simultaneous oxidation and removal on a MnO2-loaded polystyrene resin.

Study of the spatial and historical distribution of sediment inorganic contamination in the Toulon bay (France).

Arsenic removal by adsorption on iron(III) phosphate