about
Life cycle assessment to evaluate the environmental impact of biochar implementation in conservation agriculture in Zambia.Remediation of contaminated marine sediment using thin-layer capping with activated carbon--a field experiment in Trondheim harbor, Norway.Effect of activated carbon amendment on bacterial community structure and functions in a PAH impacted urban soilBioassay-directed identification of toxic organic compounds in creosote-contaminated groundwater.The sorption and desorption of phosphate-P, ammonium-N and nitrate-N in cacao shell and corn cob biochars.Estimating the in situ sediment-porewater distribution of PAHs and chlorinated aromatic hydrocarbons in anthropogenic impacted sediments.Stakeholder involvement for management of the coastal zone.State-of-the-lagoon reports as vehicles of cross-disciplinary integration.The contribution of urban runoff to organic contaminant levels in harbour sediments near two Norwegian cities.Influence of historical industrial epochs on pore water and partitioning profiles of polycyclic aromatic hydrocarbons and polychlorinated biphenyls in Oslo Harbor, Norway, sediment cores.Field measurement of diffusional mass transfer of HOCs at the sediment-water interface.Strong sorption of native PAHs to pyrogenic and unburned carbonaceous geosorbents in sediments.Experimental determination of efficiency of capping materials during consolidation of metal-contaminated dredged material.Treatment of air pollution control residues with iron rich waste sulfuric acid: does it work for antimony (Sb)?Photochemical degradation of benzotriazole.Biodegradation of soluble aromatic compounds of jet fuel under anaerobic conditions: laboratory batch experiments.Estimating the availability of polycyclic aromatic hydrocarbons for bioremediation of creosote contaminated soils.Antimony (Sb) contaminated shooting range soil: Sb mobility and immobilization by soil amendments.Use of life cycle assessments to evaluate the environmental footprint of contaminated sediment remediation.Sorption characteristics of polycyclic aromatic hydrocarbons in aluminum smelter residues.Diffusion of PAH and PCB from contaminated sediments with and without mineral capping; measurement and modelling.In situ measurement of PCB pore water concentration profiles in activated carbon-amended sediment using passive samplers.Sedimentation and chronology of heavy metal pollution in Oslo harbor, Norway.Tributyltin sorption to marine sedimentary black carbon and to amended activated carbon.Investigation of hydrogeologic processes in a dipping layer structure: 2. Transport and biodegradation of organics.Relation between PAH and black carbon contents in size fractions of Norwegian harbor sediments.Field testing of equilibrium passive samplers to determine freely dissolved native polycyclic aromatic hydrocarbon concentrations.Assessing PAH and PCB emissions from the relocation of harbour sediments using equilibrium passive samplers.Sorbent amendment as a remediation strategy to reduce PFAS mobility and leaching in a contaminated sandy soil from a Norwegian firefighting training facility.Bioaccumulation of native polycyclic aromatic hydrocarbons from sediment by a polychaete and a gastropod: freely dissolved concentrations and activated carbon amendment.Predicting low biota to sediment accumulation factors of PAHs by using infinite-sink and equilibrium extraction methods as well as BC-inclusive modeling.Antimony (Sb) and lead (Pb) in contaminated shooting range soils: Sb and Pb mobility and immobilization by iron based sorbents, a field study.Large-scale field study on thin-layer capping of marine PCDD/F-contaminated sediments in Grenlandfjords, Norway: physicochemical effectsSpatial and Temporal Changes of Jet Fuel Contamination in an Unconfined Sandy AquiferNutrient-limited biodegradation of PAH in various soil strata at a creosote contaminated siteSorption of triazoles to soil and iron mineralsInfiltration and redistribution of LNAPL into unsaturated layered porous mediaColumn studies on transport of deicing additive benzotriazole in a sandy aquifer and a zerovalent iron barrierPassive samplers versus surfactant extraction for the evaluation of PAH availability in sediments with variable levels of contaminationHow quality and quantity of organic matter affect polycyclic aromatic hydrocarbon desorption from Norwegian harbor sediments
P50
Q30583509-7CD5F9BD-43E1-425F-98F4-E0E9CAE04299Q33931972-3EFC647D-278E-4DCA-924B-3D805C994813Q34210863-B3E6E781-DA77-493F-A912-2D891A464213Q34551673-6AF91B9C-8BB3-4100-8817-46E45055B6E1Q34570272-07F8048D-04BF-4B01-814D-87A5E2DB01F9Q37592184-61680EA6-0BB6-4713-9BAD-FE5542821310Q38804367-108FF976-0083-4DDE-A707-A4543C7567F9Q38858340-BF7C6ECD-B93A-4E69-9E94-EA62B4C9DA7DQ39830864-33A6B02E-1379-489E-9EFC-94CC4FF27493Q39970116-5360250B-83E7-451C-904F-79117A7E57D5Q42939809-1C9B8188-7BD8-46E5-9895-45CF454F4DC0Q43333407-AC446381-AF3E-4F1D-B41C-B2AAEDBF781AQ43350193-00D636EB-2877-49C7-B24D-0EE369FEAD17Q43355713-4A4F5115-65E9-4DF4-BC4B-C0D89BE2BA2FQ43362107-8811FCAE-3DE2-42F2-8E59-18C1B605436EQ43837038-BE943B5D-004F-4850-9699-F28FE470098CQ44526386-DCD286F6-38E9-4AD4-B4F2-B85EB44C33C4Q45185614-774F2B6C-5401-4EB8-8FD6-E6B1CABEB013Q46067084-441E403E-4A0E-42C1-8E59-3CF895140E83Q46329207-90F1FE01-BA72-4789-93E4-DFC95A20ABC7Q46705403-718E1E15-917E-48C3-B91A-94511DF0CDFDQ46970690-E28AAB08-D3EE-489A-A902-9E92A0332461Q47262231-47CE5E84-680C-46B3-AF8B-C2B19C418A89Q47285213-C5EA244A-DD9E-4261-97C8-6B7F8D89F98AQ47309285-1AA16634-D155-494F-96E4-851DE632BE75Q47363761-5F0A781F-6599-40D9-A076-3C1F0D920301Q47670009-CE3AF7AA-9940-4E0B-9E46-E75B7F3A42C0Q47672081-3D294396-358D-4069-937A-CFD53F551656Q48892337-14CFA68E-295B-4583-BB13-11B23ADBC436Q51130852-00EEE8BE-6F32-4B75-9748-B4FA45E59D85Q51282794-AF16A79C-8D93-4C8B-9F41-CFC8C04152C6Q51550323-F78C4B7D-04B1-41EA-B3F6-CF2B3916B805Q57218178-8C4A441F-1DD0-4ADA-9D1E-E18934867368Q59837912-1C072564-F0C0-45F3-B6AC-B027148F8232Q74594685-6690CA07-D1E2-4078-9C90-E2DEAD4AB0B9Q79379124-0637AC34-C17A-4CDE-B2D5-8F3A6EFAFDCFQ80092949-81AB444B-7FC3-4C36-83A2-9348B7DF327BQ80519581-FD2A78EC-E518-49B9-8A46-9FEA12BDB9A6Q80693208-DE98F38C-A65C-4053-B7E2-B4236AECF720Q83354267-3D237913-1ED9-44FC-A877-8155343C166F
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Gijs D. Breedveld
@ast
Gijs D. Breedveld
@en
Gijs D. Breedveld
@es
Gijs D. Breedveld
@nl
Gijs D. Breedveld
@sl
type
label
Gijs D. Breedveld
@ast
Gijs D. Breedveld
@en
Gijs D. Breedveld
@es
Gijs D. Breedveld
@nl
Gijs D. Breedveld
@sl
prefLabel
Gijs D. Breedveld
@ast
Gijs D. Breedveld
@en
Gijs D. Breedveld
@es
Gijs D. Breedveld
@nl
Gijs D. Breedveld
@sl
P106
P1153
7003715563
P21
P31
P496
0000-0003-2944-840X