FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2018962779> ?p ?o ?g. }

• W2018962779 endingPage "918" @default.
• W2018962779 startingPage "908" @default.
• W2018962779 abstract "Column leaching tests are closer to natural conditions than batch shaking tests and in the last years have become more popular for assessing the release potential of pollutants from a variety of solids such as contaminated soils, waste, recycling and construction materials. Uncertainties still exist regarding equilibration of the percolating water with the solids, that might potentially lead to underestimation of contaminant concentrations in the effluent. The intention of this paper is to show that equilibration of pore water in a finite bath is fundamentally different from release of a certain fraction of the pollutant from a sample and that equilibrium is reached much faster at low liquid-to-solid ratios typical for column experiments (<0.25) than in batch tests with much higher liquid-to-solid ratios (e.g., 2-10). Two mass transfer mechanisms are elucidated: First-order type release (film diffusion) and intraparticle diffusion. For the latter, mass transfer slows down with time and sooner or later non-equilibrium conditions are observed at the column outlet after percolation has been started. Time scales of equilibrium leaching can be estimated based on a comparison of column length with the length of the mass transfer zone, which is equivalent to a Damköhler number approach. Mass transfer and diffusion coefficients used in this study apply to mass transfer mechanisms limited by diffusion in water, which is typical for release of organic compounds but also for dissolution of soluble minerals such as calcite, gypsum or similar. As a conclusion based on these theoretical considerations column tests (a) equilibrate much faster than batch leaching tests and (b) the equilibrium concentrations are maintained in the column effluent even for slow intraparticle diffusion limited desorption for extended periods of time (>days). Since for equilibration the specific surface area is crucial, the harmonic mean of the grain size is relevant (small grain sizes result in high concentrations even after short pre-equilibration of a column). The absolute time scales calculated with linear sorption and aqueous diffusion aim at organic compounds and are not valid for sparingly soluble mineral phases (e.g. metal oxides and silicates). However, the general findings on how different liquid-to-solid ratios and specific surface area influence equilibration time scales also apply to other mass transfer mechanisms." @default.
• W2018962779 created "2016-06-24" @default.
• W2018962779 creator A5011040589 @default.
• W2018962779 date "2014-05-01" @default.
• W2018962779 modified "2023-10-07" @default.
• W2018962779 title "On equilibration of pore water in column leaching tests" @default.
• W2018962779 cites W1619164700 @default.
• W2018962779 cites W2001492318 @default.
• W2018962779 cites W2003759482 @default.
• W2018962779 cites W2011570643 @default.
• W2018962779 cites W2021375900 @default.
• W2018962779 cites W2021889858 @default.
• W2018962779 cites W2028825620 @default.
• W2018962779 cites W2032344899 @default.
• W2018962779 cites W2039155437 @default.
• W2018962779 cites W2042726050 @default.
• W2018962779 cites W2044748335 @default.
• W2018962779 cites W2057117770 @default.
• W2018962779 cites W2058436382 @default.
• W2018962779 cites W2082004954 @default.
• W2018962779 cites W2083617935 @default.
• W2018962779 cites W2137094764 @default.
• W2018962779 cites W2160409241 @default.
• W2018962779 doi "https://doi.org/10.1016/j.wasman.2014.02.012" @default.
• W2018962779 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/24636008" @default.
• W2018962779 hasPublicationYear "2014" @default.
• W2018962779 type Work @default.
• W2018962779 sameAs 2018962779 @default.
• W2018962779 citedByCount "19" @default.
• W2018962779 countsByYear W20189627792015 @default.
• W2018962779 countsByYear W20189627792016 @default.
• W2018962779 countsByYear W20189627792017 @default.
• W2018962779 countsByYear W20189627792019 @default.
• W2018962779 countsByYear W20189627792020 @default.
• W2018962779 countsByYear W20189627792021 @default.
• W2018962779 countsByYear W20189627792022 @default.
• W2018962779 crossrefType "journal-article" @default.
• W2018962779 hasAuthorship W2018962779A5011040589 @default.
• W2018962779 hasBestOaLocation W20189627791 @default.
• W2018962779 hasConcept C121332964 @default.
• W2018962779 hasConcept C147455438 @default.
• W2018962779 hasConcept C147789679 @default.
• W2018962779 hasConcept C159390177 @default.
• W2018962779 hasConcept C159750122 @default.
• W2018962779 hasConcept C178790620 @default.
• W2018962779 hasConcept C185592680 @default.
• W2018962779 hasConcept C191897082 @default.
• W2018962779 hasConcept C192562407 @default.
• W2018962779 hasConcept C2779229104 @default.
• W2018962779 hasConcept C39432304 @default.
• W2018962779 hasConcept C43617362 @default.
• W2018962779 hasConcept C51038369 @default.
• W2018962779 hasConcept C69357855 @default.
• W2018962779 hasConcept C82685317 @default.
• W2018962779 hasConcept C87717796 @default.
• W2018962779 hasConcept C88380143 @default.
• W2018962779 hasConcept C90982505 @default.
• W2018962779 hasConcept C97355855 @default.
• W2018962779 hasConceptScore W2018962779C121332964 @default.
• W2018962779 hasConceptScore W2018962779C147455438 @default.
• W2018962779 hasConceptScore W2018962779C147789679 @default.
• W2018962779 hasConceptScore W2018962779C159390177 @default.
• W2018962779 hasConceptScore W2018962779C159750122 @default.
• W2018962779 hasConceptScore W2018962779C178790620 @default.
• W2018962779 hasConceptScore W2018962779C185592680 @default.
• W2018962779 hasConceptScore W2018962779C191897082 @default.
• W2018962779 hasConceptScore W2018962779C192562407 @default.
• W2018962779 hasConceptScore W2018962779C2779229104 @default.
• W2018962779 hasConceptScore W2018962779C39432304 @default.
• W2018962779 hasConceptScore W2018962779C43617362 @default.
• W2018962779 hasConceptScore W2018962779C51038369 @default.
• W2018962779 hasConceptScore W2018962779C69357855 @default.
• W2018962779 hasConceptScore W2018962779C82685317 @default.
• W2018962779 hasConceptScore W2018962779C87717796 @default.
• W2018962779 hasConceptScore W2018962779C88380143 @default.
• W2018962779 hasConceptScore W2018962779C90982505 @default.
• W2018962779 hasConceptScore W2018962779C97355855 @default.
• W2018962779 hasIssue "5" @default.
• W2018962779 hasLocation W20189627791 @default.
• W2018962779 hasLocation W20189627792 @default.
• W2018962779 hasOpenAccess W2018962779 @default.
• W2018962779 hasPrimaryLocation W20189627791 @default.
• W2018962779 hasRelatedWork W2022199452 @default.
• W2018962779 hasRelatedWork W2039816958 @default.
• W2018962779 hasRelatedWork W2355591390 @default.
• W2018962779 hasRelatedWork W2379725571 @default.
• W2018962779 hasRelatedWork W2387556517 @default.
• W2018962779 hasRelatedWork W2793172274 @default.
• W2018962779 hasRelatedWork W2969768078 @default.
• W2018962779 hasRelatedWork W3006540667 @default.
• W2018962779 hasRelatedWork W3162753184 @default.
• W2018962779 hasRelatedWork W4238028352 @default.
• W2018962779 hasVolume "34" @default.
• W2018962779 isParatext "false" @default.
• W2018962779 isRetracted "false" @default.
• W2018962779 magId "2018962779" @default.
• W2018962779 workType "article" @default.