about
Arsenic Mobilization Is Enhanced by Thermal Transformation of Schwertmannite.Iron and arsenic cycling in intertidal surface sediments during wetland remediation.Arsenic mobilization in a seawater inundated acid sulfate soil.Effect of cyclic redox oscillations on water quality in freshwater acid sulfate soil wetlands.Arsenic mobility during flooding of contaminated soil: the effect of microbial sulfate reduction.Diffusive Gradients in Thin Films Reveals Differences in Antimony and Arsenic Mobility in a Contaminated Wetland Sediment during an Oxic-Anoxic Transition.Antimony and arsenic partitioning during Fe2+-induced transformation of jarosite under acidic conditions.Phosphate-Imposed Constraints on Schwertmannite Stability under Reducing Conditions.Antimony and Arsenic Behavior during Fe(II)-Induced Transformation of Jarosite.Iron and sulfur cycling in acid sulfate soil wetlands under dynamic redox conditions: A review.Acidic drainage drives anomalous rare earth element signatures in intertidal mangrove sediments.Iron-Monosulfide Oxidation in Natural Sediments: Resolving Microbially Mediated S Transformations Using XANES, Electron Microscopy, and Selective ExtractionsArsenic effects and behavior in association with the Fe(II)-catalyzed transformation of schwertmanniteReactive trace element enrichment in a highly modified, tidally inundated acid sulfate soil wetland: East Trinity, AustraliaPartitioning of metals in a degraded acid sulfate soil landscape: influence of tidal re-inundationPore water sampling in acid sulfate soils: a new peeper methodSorption of arsenic(V) and arsenic(III) to schwertmanniteSulfate availability drives divergent evolution of arsenic speciation during microbially mediated reductive transformation of schwertmannitePhosphate loading alters schwertmannite transformation rates and pathways during microbial reductionA new pathway for hexavalent chromium formation in soil: Fire-induced alteration of iron oxidesChromium(VI) formation via heating of Cr(III)-Fe(III)-(oxy)hydroxides: A pathway for fire-induced soil pollutioniAMES: An inexpensive, Automated Methane Ebullition SensorHumic acid impacts antimony partitioning and speciation during iron(II)-induced ferrihydrite transformationAre methane emissions from mangrove stems a cryptic carbon loss pathway? Insights from a catastrophic forest mortalityAntimony speciation and mobility during Fe(II)-induced transformation of humic acid-antimony(V)-iron(III) coprecipitates
P50
Q38412679-C4562160-6E9F-46C0-8F3C-AD501F398478Q39782905-5F338EB9-BF3B-48B1-BD0B-3AD5A186A338Q39900658-AD38CDD0-FE25-4403-AE6F-09D48E88B3B5Q46435807-89D5C89C-CB45-4197-BAE7-444AA561B54FQ46821441-34A05DF0-B653-4584-A8E3-1BEE5037E4F4Q47730902-DEA7924C-61A5-4238-9707-044EB2FBC2F8Q47741611-5174E299-5EE6-44E1-AA5D-585E3B0B094AQ48308409-FD95FA83-4889-458E-BB9D-8A15DA767069Q48356130-888D2243-C1C8-47E0-B41E-9F8759D8BDF4Q50172484-1BCE3340-BDAE-4F41-BF24-E86D1185DB5AQ53083764-0398DF85-3A68-46AC-8D44-F5F7B46655FBQ57889206-35F19FF1-B8CD-473E-8848-FAE2DA6AE480Q82864365-483956F8-9F67-4215-AA4F-62EE1015B0E5Q83179489-0D49E10B-16CF-42EB-BDF7-285AF51488ABQ84706119-145A5C16-C35C-4458-A894-6344F10F9EF4Q84817356-391A25EC-24DE-467E-8665-E1FC6F5A99FEQ84921440-100A9BFA-923A-405E-A077-C25336CE0E3BQ86039464-EA85B487-262E-4433-9F84-BCC7E3893B16Q91201892-6BF644AF-50FD-4DF4-ABC7-AC07BB9F32E6Q91318192-DA2B3442-25D0-4CB2-B62D-9773C673985EQ91333783-6ECAEAF9-25D0-4431-93DB-D9D79590F7C7Q92221430-DA471B1D-9767-4429-8502-5E6A2D1665C6Q92375447-4E25FEFC-EFBB-4106-A443-A7A08BDDA1E3Q92847218-73E81A3C-F5F4-4B76-BAF2-F9C7EEEB364CQ93075857-ADB2C3AE-B795-40E4-8499-64DB9D56C58E
P50
description
researcher ORCID ID = 0000-0002-5826-5613
@en
wetenschapper
@nl
name
Scott G Johnston
@ast
Scott G Johnston
@en
Scott G Johnston
@es
Scott G Johnston
@nl
type
label
Scott G Johnston
@ast
Scott G Johnston
@en
Scott G Johnston
@es
Scott G Johnston
@nl
prefLabel
Scott G Johnston
@ast
Scott G Johnston
@en
Scott G Johnston
@es
Scott G Johnston
@nl
P108
P106
P1153
36967564700
P31
P496
0000-0002-5826-5613