Environmental Engineering Reference
In-Depth Information
Cullen WR (2008) Is arsenic an aphrodisiac? The sociochemistry of an element. The Royal Society
of Chemistry
Cutler JN, Jiang DT, Remple G (2001) Chemical speciation of arsenic in uranium mine tailings by
X- ray absorption spectroscopy. Can J Anal Sci Spectrosc 46:130-135
Datta R, Makris KC, Sarkar D (2007) Arsenic fractionation and bioaccessibility in two alka-
line texas soils incubated with sodium arsenate. Archiv Environ Contamin Toxicol 52:
475-482
Datta R, Sarkar D, Sharma S (2006) Arsenic biogeochemistry and human health risk assessment
in organo-arsenical pesticide-applied acidic and alkaline soils: an incubation study. Sci Total
Environ 372:39-48
Davis A, Bloom NS, Hee SSQ (1997) The environmental geochemistry and bioaccessibility of
mercury in soils and sediments: a review. Risk Anal 17:557-569
Davis A, Drexler JW, Ruby MV, Nicholson A (1993) Micromineralogy of mine wastes in relation
to lead bioavailability, Butte, Montana. Environ Sci Technol 27:1415-1425
Davis A, Ruby MV, Bloom M, Schoof R, Freeman G, Bergstom PD (1996a) Mineralogic
constraints on the bioavailability of arsenic in smelter-impacted soils. Environ Sci Technol
30:392-399
Davis A, Ruby MV, Bloom M, Schoof R, Freeman G, Bergstrom PD (1996b) Mineralogic con-
straints on the bioavailability of arsenic in smelter-impacted soils. Int J Rock Mech Mining Sci
33:285A
Denys S, Caboche J, Tack K, Delalain P (2007) Bioaccessibility of lead in high carbonate soils.
J Environ Sci Health Part A-Toxic/Hazardous Subst Environ Eng 42:1331-1339
Denys S, Tack K, Caboche J, Delelain P (2009) Bioaccessibility, solid phase distribution, and
speciation of Sb in soils and in digestive fluids. Chemosphere 74:711-716
Department for the Environment Food and Rural Affairs and the Environment Agency (2002)
Assessment of risks to human health from land contamination: an overview of the soil guideline
values and related research, CLR7
Dixit S, Hering JG (2003) Comparison of arsenic(V) and arsenic(III) sorption onto iron oxide
minerals: implications for arsenic mobility. Environ Sci Technol 37:4182-4189
Drexler JW, Brattin WJ (2007) An in vitro procedure for estimation of lead relative bioavailability:
with validation. Human Ecol Risk Assess 13:383-401
Duggan MJ, Inskip MJ, Rundle SA, Moorcroft JS (1985) Lead in playground dust and on the hands
of schoolchildren. Sci Total Environ 44:65-79
Ellickson KM, Meeker RJ, Gallo MA, Buckley BT, Lioy PJ (2001) Oral bioavailability of lead
and arsenic from a NIST standard reference soil material. Archiv Environ Contamin Toxicol
40:128-135
Esser KB, Bockheim JG, Helmke PA (1991) Trace-element distribution in soils formed in the
Indiana Dunes, USA. Soil Sci 152:340-350
Fendorf S, La Force MJ, Li GC (2004) Temporal changes in soil partitioning and bioaccessibility
of arsenic, chromium, and lead. J Environ Quality 33:2049-2055
Filgueiras AV, Lavilla I, Bendicho C (2002) Chemical sequential extraction for metal partitioning
in environmental solid samples. J Environ Monitor 4:823-857
Finzgar N, Tlustos P, Lestan D (2007) Relationship of soil properties to fractionation, bioavailabil-
ity and mobility of lead and zinc in soil. Plant Soil Environ 53:225-238
Foster AL, Brown GE, Tingle TN, Parks GA (1998) Quantitative arsenic speciation in mine tailings
using X-ray absorption spectroscopy. Am Mineral 83:553-568
Fowles J, Weinstein P, Tseng C-H (2005) Chapter 22, Environmental medicine in essentials
of medical geology: impacts of the natural environment on public health. Ed Olle Selinus.
Elsevier
Freeman GB, Dill JA, Johnson JD, Kurtz PJ, Parham F, Mathews HB (1996) Comparative absorp-
tion of lead from contaminated soil and lead salts by weanling fischer 344 rats. Fundamental
Appl Toxicol 33:109-119
Search WWH ::
Custom Search