Artificial biocrust establishment on materials of potash tailings piles along a salinity gradient

Biocrust communities provide a pallet of ecosystem services, such as soil stabilization, altering of hydrological cycles and primary production, and often are the first colonizers of unvegetated surfaces during succession. Therefore, artificially establishing biocrusts can improve soil properties, f...

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Veröffentlicht in:	Journal of applied phycology 2022-02, Vol.34 (1), p.405-421
Hauptverfasser:	Sommer, V., Palm, A., Schink, A., Leinweber, P., Gose, N., Karsten, U., Glaser, K.
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Sprache:	eng
Schlagworte:	Alginic acid Biomedical and Life Sciences Chlorophyll Chlorophyll a Dune sand Dunes Ecology Ecosystem services Electrical conductivity Electrical resistivity Fertilizers Freshwater & Marine Ecology Hydrologic cycle Hydrological cycle Hydrology Life Sciences Mine tailings Nutrients Photosynthesis Phytoplankton Piles Plant Physiology Plant Sciences Pollution Potash Potassium carbonate Primary production Restoration Salinity gradients Sand Seaweed meal Seepage Sodium Sodium alginate Sodium chloride Soil erosion Soil improvement Soil properties Soil stabilization Soil surfaces Stabilizing Substrates Tailings
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creator	Sommer, V. Palm, A. Schink, A. Leinweber, P. Gose, N. Karsten, U. Glaser, K.
description	Biocrust communities provide a pallet of ecosystem services, such as soil stabilization, altering of hydrological cycles and primary production, and often are the first colonizers of unvegetated surfaces during succession. Therefore, artificially establishing biocrusts can improve soil properties, for example, by stabilizing bare soil surfaces against erosion or by accumulating nutrients. In this study, the establishment of artificial biocrusts was tested for the restoration of potash tailings piles that result from potash fertilizer production and mostly consist of NaCl. A biocrust cover as primary vegetation could decrease the saline seepage waters by trapping rainwaters, thereby reducing the environmental pollution. In a laboratory experiment, we created a salt gradient by mixing the tailings materials with non-saline dune sand. Surface material of the abandoned potash tailings pile Neuhof-Ellers (NE) and material of the Infiltration Hampering Stratum (IHS) were tested, along with a treatment with bone char plus (BC plus ) and sodium alginate. A mixture of 50% (w/w) IHS and dune sand was most successful for the establishment of green biocrust microalgae, based on increased biomass and photosynthetic performance. The chlorophyll a content was negatively correlated with the electrical conductivity (EC), and was significantly increased in the BC plus and sodium alginate treatment, while biocrusts failed to establish on pure tailings piles substrates. The limit of the substrates EC for biocrust establishment was 35 mS cm −1 . This limit provides a baseline for future studies that should use BC plus and sodium alginate to increase the success of biocrust establishment on potash tailings piles.
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subjects	Alginic acid Biomedical and Life Sciences Chlorophyll Chlorophyll a Dune sand Dunes Ecology Ecosystem services Electrical conductivity Electrical resistivity Fertilizers Freshwater & Marine Ecology Hydrologic cycle Hydrological cycle Hydrology Life Sciences Mine tailings Nutrients Photosynthesis Phytoplankton Piles Plant Physiology Plant Sciences Pollution Potash Potassium carbonate Primary production Restoration Salinity gradients Sand Seaweed meal Seepage Sodium Sodium alginate Sodium chloride Soil erosion Soil improvement Soil properties Soil stabilization Soil surfaces Stabilizing Substrates Tailings
title	Artificial biocrust establishment on materials of potash tailings piles along a salinity gradient
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