Record Display for the EPA National Library Catalog


OLS Field Name OLS Field Data
Main Title Residual Oxidant Decay and Bromate Formation in Chlorinated and Ozonated Sea-Water.
Author Richardson, Leonard B. ; Burton, Dennis T. ; Helz,, George R. ; Rhoderick, John C. ;
CORP Author Academy of Natural Sciences of Philadelphia, Benedict, MD. Benedict Estuarine Research Lab.;Environmental Research Lab., Gulf Breeze, FL.
Year Published 1981
Report Number EPA-R-804683; EPA-600/J-81-476 ; ERL.GB-0182
Stock Number PB82-128182
Additional Subjects Water pollution control ; Sea water ; Estuaries ; Ozonation ; Chlorination ; Oxidizers ; Bromates ; Concentration(Composition) ; Decay ; Sampling ; Bromides ; Sunlight ; Photochemical reactions ; Inhibitors ; Ammonia ; Nitrogen ; Reprints ; Antifouling agents ; Free radicals ; Chemical reaction mechanisms
Library Call Number Additional Info Location Last
NTIS  PB82-128182 Most EPA libraries have a fiche copy filed under the call number shown. Check with individual libraries about paper copy. 06/23/1988
Collation 7p
Oxidant decay and bromate formation were studied under light and dark conditions in 5, 15 and 30% artificial sea-water and approximately equal to 5% natural estuarine water following ozonation or chlorination. For both oxidants, light exposure accelerated the residual oxidant decay rates which were inversely related to sample salinities in artificial sea-water. Significant quantities of bromate were produced in light-exposed, chlorinated samples with an initial residual oxidant concentration of approximately equal to 70 micrometers approximately equal to 5 mg/l as total residual chlorine but not at lower residual oxidant concentrations or in non-photolyzed samples. No bromate was formed in any of the chlorinated natural estuarine water samples. Bromate production was much greater in ozonated samples than in chlorinated ones and was formed in two distinct stages. Photolytic bromate formation decreased with increasing bromide concentration in both chlorinated and ozonated artificial sea-water. Bromate formation was completely inhibited in the presence of NH3-N and estuarine sediment. The same free radical mechanism is proposed for both ozone-induced and photolytic-induced bromate formation in artificial sea-water. (Copyright (c) 1981 Pergamon Press Ltd.)