Fuel Oxygenates [electronic resource] / edited by Damià Barceló
- Barceló, Damià
- Additional Titles:
- With contributions by numerous experts
- Berlin, Heidelberg : Springer Berlin Heidelberg : Imprint: Springer, 2007.
- Physical Description:
- XVI, 411 pages : online resource
- Additional Creators:
- SpringerLink (Online service)
- The Handbook of Environmental Chemistry, 1867-979X
- T. Schmidt and M.A. Jochmann: Novel Analytical Methods for the Determination of Fuel Oxygenates in Water -- M. Rosell, S. Lacorte and D. Barceló: Occurrence and Fate of MTBE in the Aquatic Environment over the last Decade -- M.J. Moran: Occurrence of Methyl tert-Butyl Ether and other Fuel Oxygenates in Source Water and Drinking Water of the United States -- B. Babé, D. Labbé, F. Monot, C.W. Greer and F. Fayolle-Guichard: Biodegradability of Oxygenates by Microflora from MTBE-Contaminated Sites: New Molecular Tools -- M. Rosell, M.M. Häggblom and H. Richnow: Compound Specific Isotope Analysis to Characterize Degradation Pathways and to Quantify In-Situ Degradation of Fuel Oxygenates and other Fuel-Derived Contaminants -- H.D. Stupp: Spreading of MTBE and Chlorinated Hydrocarbons in Groundwater -- M. Schirmer and M. Martienssen: Enhanced Natural Attenuation of MTBE -- L. Debor and L. Bastiaens: Bioremediation of Groundwater Contaminated with MTBE/TBA -- C. Oehm, C. Stefan, P. Werner and A. Fischer: Adsorption and Abiotic Degradation of Methyl tert-Butyl Ether (MTBE) -- C.K. Waul, E. Arvin and J.E. Schmidt: Microbial Degradation of MTBE in Reactors -- H.D. Stupp: Remediation Technologies and Costs for Cleaning MTBE Contaminated Groundwater -- C. Baus and H.-J. Brauch: Removal of MTBE and Other Fuel Oxygenate during Drinking Water Treatment -- D. McGregor: Toxicological Review of Methyl- and Ethyl-tertiary-Butyl Ethers -- J. Fawell: MTBE: WHO Guidelines and Taste and Odour Issues for Drinking Water.
- The state of the art on fuel oxygenates, and in particular of MTBE in groundwater, is presented. Historically, oxygenates like MTBE were developed in the 1970s as octane enhancers to replace toxic additives like lead, which were phased out of gasoline. The presence of oxygenates in gasoline promotes cleaner fuel combustion within the engine, boosts fuel octane values and reduces vehicle emissions. Another relevant oxygenate is ethyl-tertiary-butyl ether (ETBE), which has increasingly replaced MTBE. Ethanol is by far the most commonly used alcohol oxygenate and bio-ethanol in particular is being increasingly used as a replacement for other fuel oxygenates. Today the discussion on the increase on corn production to produce bio-ethanol in order to reduce our dependency on oil is in the press. As a consequence corn cultivation started to increase in Europe, the US and Brazil with subsidiary plans from the governments up to 0.4 Euros/liter of biethanol produced. Other alcohols that can be used as fuel oxygenates are methanol and tertiary-butyl alcohol (TBA). TBA is, in addition, the main degradation product of MTBE and a potential impurity from the MTBE manufacturing process. This book deals mainly with the problems associated with the contamination of groundwater by MTBE and TBA, but ETBE is also considered. The book, written by recognized specialists in the field, is organized in sections covering state-of-the-art analytical methods, including specific isotopic analysis, occurrence in the environment, transport and degradation processes, treatment technologies and human health risks. It offers a unique opportunity not only for scientists who want to get more comprehensive information on this subject but also for policy makers and stakeholders that need to manage real-world environmental problems associated with fuel oxygenate contamination of our groundwater resources.
- Digital File Characteristics:
- text file PDF
- AVAILABLE ONLINE TO AUTHORIZED PSU USERS.
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