http://researchonline.federation.edu.au/vital/access/manager/Index ${session.getAttribute("locale")} 5 http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:12247 Wed 07 Apr 2021 14:00:32 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10424 Wed 07 Apr 2021 13:55:47 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10423 Wed 07 Apr 2021 13:55:47 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10422 Wed 07 Apr 2021 13:55:47 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10421 Wed 07 Apr 2021 13:55:47 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10420 Wed 07 Apr 2021 13:55:47 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10418 Wed 07 Apr 2021 13:55:47 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10417 Wed 07 Apr 2021 13:55:47 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10416 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10415 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10414 . 5% may be identifiable through this approach. Our findings highlight that both the 15. min AAO extraction procedure and the DXRD analysis have limited applicability towards detecting schwertmannite accurately in soil materials. © 2015 Elsevier B.V.]]> Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10413 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10412 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10411 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10410 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10409 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10404 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10403 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10402 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10401 Wed 07 Apr 2021 13:55:46 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10400 Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10399 Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10398 Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10397 Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10396 1 m) in the underlying sulfidic horizons. δ34S data indicate that tidal inundation caused exchange of marine solutes within former sulfuric horizons, but not within underlying sulfidic material. There was considerable reformation of pyrite within former sulfuric horizons after tidal inundation with reduced inorganic sulfur increasing by ∼ 60 μmol g- 1. Acid-volatile sulfide also accumulated, but mainly near the soil surface (up to 16 μmol g- 1). Reduction of Fe(III) minerals strongly influences the geochemistry of the tidally inundated soils. After tidal inundation the soil pH and Eh closely followed the iron redox couple and there was non-sulfidic solid-phase Fe(II) up to 600 μmol g- 1. There was also substantial diagenetic enrichment of poorly crystalline Fe-oxides near the soil surface following tidal inundation, with reactive Fe spanning 400-1800 μmol g- 1. While the decreases in soil acidity documented here are likely due to a combination of marine alkalinity inputs and reduction of both Fe and SO42-, the relative importance of each process remains to be determined. This study demonstrates that marine tidal inundation can be an effective landscape-scale strategy for ameliorating severe acidity associated with drained acid sulfate soils. © 2008 Elsevier B.V. All rights reserved.]]> Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10395 30mmol L-1) in former sulfuric horizons in the upper-intertidal zone. Tidal forcing generated oscillating hydraulic gradients, driving upward advection of this Fe2+-enriched porewater along the intertidal slope. Subsequent oxidation of Fe2+ led to substantial accumulation of reactive Fe(III) fractions (up to 8000μmol g-1) in redox-interfacial, tidal zone sediments. These Fe(III)-precipitates were poorly crystalline and displayed a distinct mineralisation sequence related to tidal zonation. Schwertmannite (Fe8O8(OH)6SO4) was the dominant Fe mineral phase in the upper-intertidal zone at mainly low pH (3-4). This was followed by increasing lepidocrocite (γ-FeOOH) and goethite (α-FeOOH) at circumneutral pH within lower-intertidal and subtidal zones. Relationships were evident between Fe fractions and topography. There was increasing precipitation of Fe-sulfide minerals and non-sulfidic solid-phase Fe(II) in the lower intertidal and subtidal zones. Precipitation of Fe-sulfide minerals was spatially co-incident with decreases in porewater Fe2+. A conceptual model is presented to explain the observed landscape-scale patterns of Fe mineralisation and hydro-geochemical zonation. This study provides valuable insights into the hydro-geochemical processes caused by saline tidal inundation of low lying CASS landscapes, regardless of whether inundation is an intentional strategy or due to sea-level rise. © 2010 Elsevier B.V.]]> Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10394 Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10393 tidal exchange (25-42%)>sulfate reduction (7-13%)>>hydrated lime addition (<1%). Accurately attributing the relative contributions due to Fe and SO 4 2- reduction was limited by an inability to distinguish between non-sulfidic, solid-phase Fe(II) generated by microbial dissimilatory reduction of Fe(III) or chemical reduction of Fe(III) by H 2S. Nevertheless, the combined alkalinity contribution of these two electron accepting processes accounts for between 58 and 74% of the total. The majority (>99%) of net alkalinity generation was due to either tides or microbial metabolism. This indicates that the LATE remediation technique is both a cost effective means of decreasing soil acidity and is readily transferable to similar CASS landscapes - provided there is adequate supply of suitable electron donors and sufficient regenerative capacity in the adjacent estuarine/marine tidal HCO 3 - pool. © 2012 Elsevier B.V.]]> Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10392 95% of the As(aq) within the first 4 h of aeration. Ferrihydrite transformed to schwertmannite within 23 days, although sorbed/coprecipitated As(III) remained unoxidized during this period. Schwertmannite subsequently transformed to jarosite at low pH (2-3), accompanied by oxidation of remaining Fe 2+. This coincided with a repartitioning of some sorbed As back into the aqueous phase as well as oxidation of sorbed/coprecipitated As(III) to As(V). Fe(III) precipitates formed via groundwater aeration were highly prone to reductive dissolution, thereby posing a high risk of mobilizing sorbed/coprecipitated As during any future upward migration of redox boundaries. Longer-term investigations are warranted to examine the potential pathways and magnitude of arsenic mobilization into surface waters in tidally reflooded wetlands. © 2011 American Chemical Society.]]> Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10391 Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10390 1 m deep in acid sulfate soil or any other firm wetland soils. Copyright © 2009 by the American Society of Agronomy, Crop Science Society of America, and Soil Science Society of America. All rights reserved.]]> Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10389 Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10388 Wed 07 Apr 2021 13:55:45 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10387 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10385 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10384 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10383 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10382 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10381 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10380 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10379 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10378 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10377 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10376 5, the rates of Fe(II)-catalyzed schwertmannite transformation were several orders of magnitude faster than transformation in the absence of Fe(II). Complete transformation of schwertmannite occurred within only 3-5 h at pH > 6 and Fe(II)(aq) ≥ 5 mmol L-1. Model calculations indicate that the Fe(II)-catalyzed transformation of schwertmannite to goethite greatly decreases the reactivity of the Fe(III) pool, thereby favoring SO4-reduction and facilitating the formation of iron-sulfide minerals (particularly mackinawite, tetragonal FeS). Examination of in situ sediment geochemistry in an acid-sulfate system revealed that the rapid Fe(II)-catalyzed transformation was consistent with an abrupt shift from an acidic Fe(III)-reducing regime with abundant schwertmannite near the sediment surface, to a near-neutral mackinawite-forming regime where goethite was dominant. This study demonstrates that the Fe(II) pathway exerts a major influence on schwertmannite transformation and iron-sulfide formation in anoxic acid-sulfate systems. These findings have important implications for understanding acidity dynamics and trace element mobility in such systems. © 2008 Elsevier Ltd. All rights reserved.]]> Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10375 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10374 Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10373 4.6). Sorption of As(V) and As(III) caused significant release of SO 4 2- from within the schwertmannite solid-phase, without major degradation of the schwertmannite structure (as evident by X-ray diffraction and Raman spectroscopy). This can be interpreted as arsenic sorption via incorporation into the schwertmannite structure, rather than merely surface complexation at the mineral-water interface. The results of this study have important implications for arsenic mobility in the presence of schwertmannite, such as in areas affected by acidmine drainage and acid-sulfate soils. In particular, arsenic speciation, arsenic loading, and pH should be considered when predicting and managing arsenic mobility in schwertmanniterich systems. © 2009 American Chemical Society.]]> Wed 07 Apr 2021 13:55:44 AEST ]]> http://researchonline.federation.edu.au/vital/access/manager/Repository/vital:10372 Wed 07 Apr 2021 13:55:43 AEST ]]>