Zusammenfassung der Projektergebnisse

When acid sulfate soils dry, oxidation of pyrite can cause acidification and formation of iron (Fe) oxyhydroxy sulfate phases such as jarosite. Remediation via re-establishment of reducing conditions requires submergence and available organic carbon (OC) to stimulate activity of reducing bacteria. We identified acid sulfate soil layers low in biodegradable carbohydrates and proteins, but high in lignin and lipids that cannot be remediated by rewetting alone. Consequently, not only the amount of OC, but rather its biodegradability is decisive for the remediation success. Follow-up experiments showed that sufficient addition of fresh plant residues can activate reducing bacteria, likely due to the release of readily available soluble organic matter. However, the effectiveness of soluble organic matter from different plant residues has not been tested so far. Furthermore, it was unclear whether an additional pH adjustment to values >4.5 was necessary to activate microbial reducers (especially sulfate reducers). In contrast to previous studies, our incubation studies showed that sufficient addition of dissolved OC (DOC) induced reduction processes that consumed protons, leading to increased pH values without any pH pre-adjustments. Thus, remediation of sulfuric soils can be achieved by combining submergence and addition of plant-derived DOC, with wheat straw and litter of Phragmites australis being most suitable. Due to its potential to migrate deep into soil, application of DOC from crop residues, such as wheat straw, is a promising measure to remediate also sulfuric subsoils. We expected that the reduction processes and the increase in pH would cause jarosite to dissolve and Fe sulfides to form. Our results confirmed the dissolution of jarosite, but we did not detect the formation of Fe sulfides in any incubation experiment. Instead, we observed formation of Fe oxyhydroxides (e.g., nano-sized goethite), as well as Fe2+/Fe3+ either sorbed to minerals or associated with OC. The observed formation of Fe oxyhydroxides is advantageous with regard to the remediation of sulfuric soils containing jarosite as it reduces the risk of leaching Fe2+ to neighbouring environments and minimizes renewed acidification in the case of future aeration. An increase in mineral–organic associations was detected in all incubation experiments. Presumably, the observed formation of Fe oxyhydroxides led to a proportion of the DOC being bound to their large, reactive surfaces. The sorption of DOC on reactive mineral surfaces was particularly evident in an experimental remediation of a clayey sulfuric soil. Here, rapid sorption removed so much DOC from the soil solution that the reduction processes were greatly delayed and only started after increased extra additions of DOC. Sorption contributes to an increase in the soil OC concentration, but the OC availability for microbial processes is greatly reduced. In an accompanying study, it was shown that in addition to sorption, the encapsulation of organic matter also greatly reduces its availability: When wetlands containing Fe sulfides dry, jarosite precipitates preferentially along root channels and almost completely fill the pore space around the roots. Due to this encrustation, the organic matter of the root becomes isolated from the soil matrix and thus inaccessible to microbes. Consequently, the amount of DOC added to remediate sulfuric soils needs to be high enough to overcome sorption processes and to unlock native root organic matter encrusted by jarosite. Overall, the project provides novel insight into processes governing the biogeochemistry of sulfuric soils. These have immediate implications for developing improved strategies to remediate acid sulfate soils: application of DOC from crop residues is environmentally friendly, can also be used for subsoils and, if dosed appropriately, leads to the conversion of jarosite to Fe oxyhydroxides, which minimizes the risk of renewed acidification in the case of future aeration.

Projektbezogene Publikationen (Auswahl)

• Organic matter composition in acid sulfate soils. Oral presentation. 8th Int. Acid Sulfate Soils Conference. College Park, MD, USA, 2016
  Kölbl, A.; Marschner, P.; Fitzpatrick, R.; Mosley, L. & Kögel-Knabner, I.
  
• Linking organic matter composition in acid sulfate soils to pH recovery after re-submerging. Geoderma, 308, 350-362.
  Kölbl, Angelika; Marschner, Petra; Fitzpatrick, Rob; Mosley, Luke & Kögel-Knabner, Ingrid
  
• Organische Bodensubstanz in sulfatsauren Böden. Poster presentation. DBG 2017, Göttingen, Germany 2017
  Kölbl, A.; Marschner, P.; Fitzpatrick, R.; Mosley, L. & Kögel-Knabner, I.
  
• Remediation of acid sulphate soils: The role of organic matter. Poster presentation. Goldschmidt Conference, Paris, France, 2017
  Kölbl, A.; Marschner, P.; Fitzpatrick, R.; Mosley, L. & Kögel-Knabner, I.
  
• Alteration of organic matter during remediation of acid sulfate soils. Geoderma, 332, 121-134.
  Kölbl, Angelika; Marschner, Petra; Mosley, Luke; Fitzpatrick, Rob & Kögel-Knabner, Ingrid
  
• Decomposition of organic matter during remediation of an acid sulfate soil. Oral presentation. 21st WCSS, Rio de Janeiro, Brazil 201
  Kölbl, A.; Marschner, P.; Fitzpatrick, R.; Mosley, L. & Kögel-Knabner, I.
  
• Organic matter decomposition during remediation of acid sulfate soils. Poster presentation. EGU 2018, Vienna, Austria 2018
  Kölbl, A.; Marschner, P.; Fitzpatrick, R.; Mosley, L. & Kögel-Knabner, I.
  
• Consumption and alteration of different organic matter sources during remediation of a sandy sulfuric soil. Geoderma, 347, 220-232.
  Kölbl, Angelika; Bucka, Franziska; Marschner, Petra; Mosley, Luke; Fitzpatrick, Rob; Schulz, Stefanie; Lueders, Tillmann & Kögel-Knabner, Ingrid
  
• Porosity and organic matter distribution in jarositic phyto tubules of sulfuric soils assessed by combined µCT and NanoSIMS analysis. Geoderma, 399, 115124.
  Pohl, Lydia; Kölbl, Angelika; Uteau, Daniel; Peth, Stephan; Häusler, Werner; Mosley, Luke; Marschner, Petra; Fitzpatrick, Rob & Kögel-Knabner, Ingrid
  
• Transformation of jarosite during simulated remediation of a sandy sulfuric soil. Science of The Total Environment, 773, 145546.
  Kölbl, Angelika; Kaiser, Klaus; Winkler, Pauline; Mosley, Luke; Fitzpatrick, Rob; Marschner, Petra; Wagner, Friedrich E.; Häusler, Werner & Mikutta, Robert
  
• Kölbl, A., Kaiser, K., Winkler, P., Mosley, L., Fitzpatrick, R., Marschner, P., Häusler, W., Mikutta, R.: Transformation of jarosite during simulated remediation of a sandy sulfuric soil. Poster presentation. 22nd WCSS, Glasgow, United Kingdom, 2022
  Kölbl, A.; Kaiser, K.; Winkler, P.; Mosley, L.; Fitzpatrick, R.; Marschner, P.; Häusler, W. & Mikutta, R.
  
• Rapid remediation of sandy sulfuric subsoils using straw-derived dissolved organic matter. Geoderma, 420, 115875.
  Kölbl, Angelika; Kaiser, Klaus; Thompson, Aaron; Mosley, Luke; Fitzpatrick, Rob; Marschner, Petra; Sauheitl, Leopold & Mikutta, Robert
  
• Importance of mineral-organic matter interactions for remediation of acid sulfate soils by submergence and organic matter addition. Oral presentation. 9th International Acid Sulfate Soils Conference 2023. Adelaide, Australia 2023. (KEYNOTE SPEAKER)
  Kölbl, A.; Kaiser, K.; Mikutta, R.; Winkler, P.; Schulz, S.; Bucka, F.; Häusler, W.; Kögel-Knabner, I.; Fitzpatrick, R.; Marschner, P.; Mosley, L. & Thompson, A.
  
• Sorption retards remediation of clayey sulfuric soils with straw‐derived dissolved organic matter. European Journal of Soil Science, 75(5).
  Kölbl, Angelika; Mosley, Luke; Fitzpatrick, Rob & Kaiser, Klaus