LEADER 06282nam a2200397Ii 4500
001 991003219599707536
008 070806s2005    mauab   sb    001 0 eng d
020   $a9780750678766
020   $a0750678763
035   $ab13650555-39ule_inst
040   $aBibl. Dip.le Aggr. Ingegneria Innovazione - Sez. Ingegneria Innovazione$beng
082 04$a628.1$222
100 1 $aSullivan, Patrick J.$0145191
245 14$aThe environmental science of drinking water$h[e-book] /$cPatrick J. Sullivan, Franklin J. Agardy, James J.J. Clark
260   $aBurlington, MA :$bElsevier Butterworth-Heinemann,$cc2005
300   $axiii, 368 p. :$bill., map ;$c24 cm
504   $aIncludes bibliographical references and index
505 0 $a1. The water we drink: Natural water. Water and the public health -- 2. Water pollution: Human waste and pollution. Industrial pollution. Wastewater control and treatment. Nonpoint sources of water pollution. Pollution sources and water quality -- 3. Water protection: The basics of water supply. Basic water treatment. Beyond basic water treatment. An issue of equality. Chemical monitoring and warnings for regulated pollutants. The National drinking water contaminant occurrence database. Unregulated pollutants and monitoring regulations. Setting new drinking water standards. Why consumers should be concerned. Approaches to mitigate chemical exposure. Water pollution and risk -- 4. Living with the risk of polluted water: The burden of proof. Permissible pollution. The dose makes the poison. Basic concepts of dose. Mechanism of toxicity. Biotransformation and detoxification. Toxicity and defining standards. Timing is everything. Endocrine-disrupting chemicals. Pharmaceutical pollutants. Pharmaceuticals detected in the environment. Living with risk. Population, pollution, risk, and precaution. The risk assessment process -- 5. Managing risk and drinking water quality: Learning from the past and present. Risk and economics. An alternative approach. Consumer-based protection. Potential action by the water industry. Potential governmental actions. An alternative risk management program -- Appendices: 1-1. Average elemental abundance in the earth's crust -- 1-2. Chemical compounds with established water quality criteria--1952 -- 1-3. USEPA national recommended water quality criteria for freshwater and human consumption of water + organism: 2002 -- 2-1. Dow industrial chemicals, solvents and dyes in 1938 -- 2-2. USEPA list of priority pollutants -- 2-3. Summary of surface water data -- 2-4. Summary of shallow groundwater data -- 2-5. Organic chemicals found in landfill leachate and gas -- 2-6. Unregulated pollutants discharged to or identified in water resources -- 2-7. Chemicals known to the state of California to cause cancer or reproductive toxicity -- 2-8. Regulated pesticides in food with residue tolerances -- 2-9. Comparison of chemicals required to be monitored in groundwater by RCRA -- 3-1. General drinking water monitoring and warning requirements (as of 2002) -- 3-2. National drinking water contaminant occurrence database: data on primary water quality standards (May 18, 2001) -- 3-3. National drinking water contaminant occurrence database: data on unregulated compounds -- 3-4. Examples of bottled mineral water chemistry -- 3-5. Examples of bottled water chemistry -- 3-6. Trace element analysis of mineral waters (ppb) that appear in either appendix 3-4 or appendix 3-5 -- 4-1. Glossary of terms adapted from the International Union of Pure and Applied Chemistry (IUPAC) (1993) -- 4-2. Chemical examples on the toxicology of drinking water standards -- 4-3. Suspected endocrine-disrupting chemicals -- 4-4. U.S. Geological Survey target compounds, national reconnaissance of emerging contaminants in U.S. streams (2000)
520   $aIn todays chemically dependent society, environmental studies demonstrate that drinking water in developed countries contains numerous industrial chemicals, pesticides, pharmaceuticals and chemicals from water treatment processes. This poses a real threat. As a result of the ever-expanding list of chemical and biochemical products industry, current drinking water standards that serve to preserve our drinking water quality are grossly out of date. Environmental Science of Drinking Water demonstrates why we need to make a fundamental change in our approach toward protecting our drinking water. Factual and circumstantial evidence showing the failure of current drinking water standards to adequately protect human health is presented along with analysis of the extent of pollution in our water resources and drinking water. The authors also present detail of the currently available state-of-the-art technologies which, if fully employed, can move us toward a healthier future. * Addresses the international problems of outdated standards and the overwhelming onslaught of new contaminants. * Includes new monitoring data on non-regulated chemicals in water sources and drinking water. * Includes a summary of different bottled waters as well as consumer water purification technologies
533   $aElectronic reproduction.$bAmsterdam :$cElsevier Science & Technology,$d2007.$nMode of access: World Wide Web.$nSystem requirements: Web browser.$nTitle from title screen (viewed on Aug. 2, 2007).$nAccess may be restricted to users at subscribing institutions
650  0$aWater-supply
650  0$aDrinking water
650  0$aWater$xPollution
650  0$aWater quality management
655  7$aElectronic books.$2local
700 1 $aAgardy, Franklin J.
700 1 $aClark, James J. J.
776 1 $cOriginal$z0750678763$z9780750678766$w(DLC)  2005009795$w(OCoLC)59403349
856 40$3Referex$uhttp://www.sciencedirect.com/science/book/9780750678766$zAn electronic book accessible through the World Wide Web; click for information
856 41$zTable of contents only$uhttp://www.loc.gov/catdir/toc/ecip0511/2005009795.html
856 42$zPublisher description$uhttp://catdir.loc.gov/catdir/enhancements/fy0622/2005009795-d.html
907   $a.b13650555$b03-03-22$c24-01-08
912   $a991003219599707536
996   $aEnvironmental science of drinking water$91213446
997   $aUNISALENTO
998   $ale026$b24-01-08$cm$d@  $e-$feng$gmau$h4$i0