Environmental Engineering Reference
In-Depth Information
editors.
The Global Arsenic Problem: Challenges for Safe Water Production
. London: CRC Press/Balkema, Taylor & francis group;
2010. p 209-218.
[49] Meichtry JM, Lin HJ, de la fuente L, Levy IK, gautier eA, Blesa MA, Litter MI. Low-cost TiO
2
photocatalytic technol-ogy for water
potabilization in plastic bottles for isolated regions. Photocatalyst fixation. J Sol energy-T ASMe 2007;129:119-126.
[50] fostier AH, Pereira Mdo SS, Rath S, guimarães JR. Arsenic removal from water employing heterogeneous photocatalysis with TiO
2
immobilized in PeT bottles. Chemosphere 2008;72:319-324.
[51] Vinodgopal K, wynkoop de, Kamat PV. environmental photochemistry on semiconductor surfaces: photosensitized degradation of a
textile azo dye, Acid Orange 7, on TiO
2
particles using visible light. environ Sci Technol 1996;30:1660-1666.
[52] Park y, Lee SH, Kang SO, Choi w. Organic dye-sensitized TiO
2
for the redox conversion of water pollutants under visible light. Chem
Commun 2010;46:2477-2479.
[53] Li Q, easter NJ, Shang JK. As(III) removal by palladium-modified nitrogen-doped titanium oxide nanoparticle photocatalyst. environ
Sci Technol 2009;43:1534-1539.
[54] Monllor-Satoca d, gómez R, Choi w. Concentration-dependent photoredox conversion of As(III)/As(V) on illuminated titanium
dioxide electrodes. environ Sci Technol 2012;46:5519-5527.
[55] yoon S-H, Lee S, Kim T-H, Lee M, yu S. Oxidation of methylated arsenic species by UV/S
2
O
8
2−
. Chem eng J 2011;173:290-295.
[56] Cullen wR, Reimer KJ. Arsenic speciation in the environment. Chem Rev 1989;89:713-764.
[57] Bednar AJ, garbarino JR, ferrer I, Rutherford dw, wershaw RL, Ranville Jf, wildeman TR. Photodegradation of roxarsone in poultry
litter leachates. Sci Total environ 2003;302:237-245.
[58] Zheng S, Cai y, O'Shea Ke. TiO
2
photocatalytic degradation of phenylarsonic acid. J Photochem Photobiol A 2010;210:61-68.
[59] xu Z, Jing C, Li f, Meng x. Mechanisms of photocatalytical degradation of monomethylarsonic and dimethylarsinic acids using
nanocrystalline titanium dioxide. environ Sci Technol 2008;42:2349-2354.
[60] wHO. guidelines for drinking-water quality, third edition incorporating the first and second addenda. Volume 1. Recommendations. 3rd
ed. geneva: wHO; 2008.
[61] Baral A, engelken Rd. Chromium-based regulations and greening in metal finishing industries in the USA. environ Sci Policy
2002;5:121-133.
[62] gauglhofer J, Bianchi V.
Metals and Their Compounds in the Environment
. weinheim: VCH; 1991.
[63] Hamilton Jw, wheterhan Ke.
Handbook of Toxicity of Inorganic Compounds
. New york: Marcel dekker, Inc.; 1988.
[64] fendorf Se, Li g. Kinetics of chromate reduction by ferrous iron. environ Sci Technol 1996;30:1614-1617.
[65] Seaman JC, Bertsch PM, Schwallie L. In situ Cr(VI) reduction within coarse-textured, oxide-coated soil and aquifer systems using
fe(II) containing solutions. environ Sci Technol 1999;33:938-944.
[66] Beukes JP, Pienaar JJ, Lachmann g, giesekke ew. The reduction of hexavalent chromium by sulphite in wastewaters. water SA
1999;25:363-370.
[67] Niki K. Chromium. In: Bard JA, Parsons R, Jordan J, editors.
Standard Potentials in Aqueous Solution
. New york: Marcel dekker, Inc.;
1985. p 453-461.
[68] distribución del arsénico en la región Ibérica e Iberoamericana. distribución del arsénico en la región Ibérica e Iberoamericana In:
Bundschuh J, Pérez Carrera A, Litter MI, editors. editorial Programa Iberoamericano de Ciencia y Tecnología para el desarrollo, octu-
bre de; Argentina. Available at http://www.cnea.gov.ar/pdfs/actividades_ambientales/LIBROdistribucionarsenico.pdf. Accessed May
31, 2014. edición CyTed. Argentina; 2008.
[69] domènech x, Muñoz J. Photochemical elimination of Cr(VI) from neutral-alkaline solutions. J Chem Technol Biotechnol
1990;47:100-107.
[70] dozzi MV, Saccomanni A, Selli e. Cr(VI) photocatalytic reduction: effects of simultaneous organics oxidation and of gold nanoparticles
photodeposition on TiO
2
. J Hazard Mater 2012;211-212:188-195.
[71] Prairie MR, evans LR, Martinez SL. Chemical oxidation: technology for the nineties. Proceedings of the second international
symposium. Volume 2. Nashville, TN; 1992. p 13.
[72] Prairie MR, evans LR, Stange BM, Martinez SL. An investigation of titanium dioxide photocatalysis for the treatment of water
contaminated with metals and organic chemicals. environ Sci Technol 1993;27:1776-1782.
[73] Prairie MR, Stange BM. Photocatalysis for the treatment of waste: Applications involving the removal of metals. AIChe Symp Ser 295
1993;89:460-465.
[74] yoneyama H, yamashita y, Tamura H. Heterogeneous photocatalytic reduction of dichromate on n-type semiconductor catalysts. Nature
1979;282:817-818.
[75] Aarthi T, Madras g. Photocatalytic reduction of metals in presence of combustion synthesized nano-TiO
2
. Catal Commun
2008;9:630-634.
[76] Aguado MA, giménez J, Cervera-March S. Continuous photocatalytic treatment of Cr(VI) effluents with semiconductor powders.
Chem eng Commun 1991;104:71-85.
