FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1552153808> ?p ?o ?g. }

• W1552153808 abstract "Lake and sea sediments act as stores for historical inputs of pollutants from both direct and diffuse sources including urbanization, agriculture, municipal and indus- trial waste waters, among others. Historical accumulation in sediments can provide a continual source of phosphorus to the water column for decades or longer after external sources have been controlled. Addition of metal salts, e.g. aluminium salts, can permanently bind this excess phosphorus in the sediment, thereby reducing internal phosphorus loading and improving water quality. Whereas this restoration method has been well studied in freshwater systems (over four decades of use), information on effectiveness in brackish and saltwater systems is limited. For this study, five sediment cores were collected from Torsbyfjarden near Lid- ingo. Sediment samples were initially analyzed for sediment phosphorus fractions and then aluminium was added to the sediment to convert mobile phosphorus to aluminum bound phosphorus. Mobile phosphorus is the pool of phosphorus that contributes directly to internal loading of phosphorus in surface waters and alumin- ium is used to convert this pool into an inert form that will remain in the sediment. Results from the initial analysis indicated that the potential for internal phosphorus loading in Torsbyfjarden is extremely high. Potential internal phosphorus loading rates ranged from 0.83 to nearly 40 mg/m2/d, with higher values generally being found in areas of greater water column depth (sediment accumulation areas). Based on the mobile phosphorus content of the sediment, aluminium was added under varying salinity (0-8) and pH (7-9) to elucidate the effects of these two vari- ables on phosphorus binding by aluminium in Baltic Sea sediment. Compared to pH, salinity had a relatively minor effect on phosphorus binding by aluminium, decreasing the effectiveness of binding by approximately 5% when comparing the 0 salinity level to a salinity of 8. pH, on the other hand, had a substantial effect on P binding by Al. The amount of mobile P inactivated by the added aluminium de- creased by approximately 22% in areas with very high mobile sediment phospho- rus and 33% in areas of moderate mobile phosphorus content in the sediment. The more important result, however, was that it may take more than twice the amount of aluminium to inactivate an equivalent amount of mobile sediment phosphorus (using pH 7 as a reference point) if pH in the treatment area is at 9 or higher. When 5 comparing pH 7 to pH 8 there was little change (approximately 5% difference) in conversion of mobile phosphorus to aluminium bound phosphorus. As part of this study, empirical models were developed to predict the effectiveness of phosphorus binding by aluminium under the above salinity and pH ranges. The overall results of this study show that the use of aluminum salts in brackish waters has good potential to limit internal phosphorus loading by inactivating the pool of mobile phosphorus via conversion to aluminium bound phosphorus. Care must be taken, however, when pH levels approach 9 or greater due to the limitation of phosphorous binding by aluminium under these conditions." @default.
• W1552153808 created "2016-06-24" @default.
• W1552153808 creator A5090442202 @default.
• W1552153808 date "2014-01-01" @default.
• W1552153808 modified "2023-09-23" @default.
• W1552153808 title "Phosphorus binding by aluminium in sediment: a tool for restoring water quality in the Baltic Sea and other brackish surface waters" @default.
• W1552153808 hasPublicationYear "2014" @default.
• W1552153808 type Work @default.
• W1552153808 sameAs 1552153808 @default.
• W1552153808 citedByCount "0" @default.
• W1552153808 crossrefType "journal-article" @default.
• W1552153808 hasAuthorship W1552153808A5090442202 @default.
• W1552153808 hasConcept C107872376 @default.
• W1552153808 hasConcept C111368507 @default.
• W1552153808 hasConcept C118178180 @default.
• W1552153808 hasConcept C122846477 @default.
• W1552153808 hasConcept C127313418 @default.
• W1552153808 hasConcept C129513315 @default.
• W1552153808 hasConcept C151730666 @default.
• W1552153808 hasConcept C178790620 @default.
• W1552153808 hasConcept C185592680 @default.
• W1552153808 hasConcept C187320778 @default.
• W1552153808 hasConcept C18903297 @default.
• W1552153808 hasConcept C2780797713 @default.
• W1552153808 hasConcept C2816523 @default.
• W1552153808 hasConcept C39432304 @default.
• W1552153808 hasConcept C510538283 @default.
• W1552153808 hasConcept C76886044 @default.
• W1552153808 hasConcept C8625798 @default.
• W1552153808 hasConcept C86803240 @default.
• W1552153808 hasConcept C87717796 @default.
• W1552153808 hasConceptScore W1552153808C107872376 @default.
• W1552153808 hasConceptScore W1552153808C111368507 @default.
• W1552153808 hasConceptScore W1552153808C118178180 @default.
• W1552153808 hasConceptScore W1552153808C122846477 @default.
• W1552153808 hasConceptScore W1552153808C127313418 @default.
• W1552153808 hasConceptScore W1552153808C129513315 @default.
• W1552153808 hasConceptScore W1552153808C151730666 @default.
• W1552153808 hasConceptScore W1552153808C178790620 @default.
• W1552153808 hasConceptScore W1552153808C185592680 @default.
• W1552153808 hasConceptScore W1552153808C187320778 @default.
• W1552153808 hasConceptScore W1552153808C18903297 @default.
• W1552153808 hasConceptScore W1552153808C2780797713 @default.
• W1552153808 hasConceptScore W1552153808C2816523 @default.
• W1552153808 hasConceptScore W1552153808C39432304 @default.
• W1552153808 hasConceptScore W1552153808C510538283 @default.
• W1552153808 hasConceptScore W1552153808C76886044 @default.
• W1552153808 hasConceptScore W1552153808C8625798 @default.
• W1552153808 hasConceptScore W1552153808C86803240 @default.
• W1552153808 hasConceptScore W1552153808C87717796 @default.
• W1552153808 hasLocation W15521538081 @default.
• W1552153808 hasOpenAccess W1552153808 @default.
• W1552153808 hasPrimaryLocation W15521538081 @default.
• W1552153808 hasRelatedWork W1591936751 @default.
• W1552153808 hasRelatedWork W2008281726 @default.
• W1552153808 hasRelatedWork W2019302055 @default.
• W1552153808 hasRelatedWork W2031811420 @default.
• W1552153808 hasRelatedWork W2142388806 @default.
• W1552153808 hasRelatedWork W2348608542 @default.
• W1552153808 hasRelatedWork W2352951746 @default.
• W1552153808 hasRelatedWork W2367800149 @default.
• W1552153808 hasRelatedWork W2370150244 @default.
• W1552153808 hasRelatedWork W2374472022 @default.
• W1552153808 hasRelatedWork W2382201044 @default.
• W1552153808 hasRelatedWork W2397179999 @default.
• W1552153808 hasRelatedWork W2550140500 @default.
• W1552153808 hasRelatedWork W2596019717 @default.
• W1552153808 hasRelatedWork W2793022763 @default.
• W1552153808 hasRelatedWork W2793341249 @default.
• W1552153808 hasRelatedWork W2977539722 @default.
• W1552153808 hasRelatedWork W3088716018 @default.
• W1552153808 hasRelatedWork W3200833662 @default.
• W1552153808 hasRelatedWork W566792425 @default.
• W1552153808 isParatext "false" @default.
• W1552153808 isRetracted "false" @default.
• W1552153808 magId "1552153808" @default.
• W1552153808 workType "article" @default.