Biological Treatment of Hazardous WastesUnlike most books on the subject, which offer only formulaic solutions to particular problems, Biological Treatment of Hazardous Wastes provides professionals with a conceptual framework within which to develop effective treatments tailored to any hazardous waste scenario they may encounter. Written by an author team comprising twenty-five North American and European experts, the text delineates the complex factors involved in the design of successful in situ and ex situ biotreatment approaches. Offering a balanced presentation of basic principles and engineering practices, it progresses from basic microbiological, biochemical, hydrogeological, and engineering principles to the development of design methodologies and specific hazardous waste scenarios - many of them based on the numerous case studies found throughout the book. |
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Page 241
... biodegradation . Chemical analyses . of contaminants , terminal electron acceptors , and / or other reactants and products indicative of biodegradation processes should be performed . Consequently , employing intrinsic bioremediation is ...
... biodegradation . Chemical analyses . of contaminants , terminal electron acceptors , and / or other reactants and products indicative of biodegradation processes should be performed . Consequently , employing intrinsic bioremediation is ...
Page 245
... biodegradation in contaminated soils . The amount of bioluminescence can be used as a quantitative measure of a pollutant's bioavailability for biodegradation . Application of bioluminescent reporter bacteria to contaminated sediments ...
... biodegradation in contaminated soils . The amount of bioluminescence can be used as a quantitative measure of a pollutant's bioavailability for biodegradation . Application of bioluminescent reporter bacteria to contaminated sediments ...
Page 257
... biodegradation rate is the Haldane equation , which is given below ( Andrews , 1968 ) : dC kXC dt C2 K1 + C + Ki ( 3 ) where K , is the inhibition constant ( mg C / L ) . Here sorption can reduce the bulk liquid concentration to lessen ...
... biodegradation rate is the Haldane equation , which is given below ( Andrews , 1968 ) : dC kXC dt C2 K1 + C + Ki ( 3 ) where K , is the inhibition constant ( mg C / L ) . Here sorption can reduce the bulk liquid concentration to lessen ...
Common terms and phrases
activity adsorbed adsorption aeration aerobic anaerobic applications aqueous aquifer aromatic bacteria Baltzis batch benzene bioavailability biodegradation biofilm biofouling Biological Treatment biomass bioreactor bioremediation bioslurry Biotech carbon chemical chlorinated clogging coefficient column composting concentration culture dechlorination DeFilippi degradation denitrification desorption diffusion effects effluent electron acceptor Engineering Environ Environmental equations ethanol factors fixed-film reactor flow foam g/m³ groundwater growth Hazardous Waste hydrocarbons hydrogen ICB system immobilized impeller increase injection kinetics Lewandowski liquid membrane metabolic methanogens mg/L microbial Microbiol microorganisms mineralization mixed Monod naphthalene nitrate nutrients occur operating organic compounds organic contaminants oxidation oxygen parameters particles Pentachlorophenol permeability reduction phase phenol pollutant pore porosity porous potential reaction recycle redox region removal sediments Shareefdeen sludge slurry slurry-phase solids solubility sorption species studies substrate subsurface surface surfactant Taylor and Jaffé temperature toluene toxicity typically vadose zone volatile wastewater zone
References to this book
Fundamentals of Environmental Chemistry, Second Edition Stanley E. Manahan No preview available - 2010 |