Azolla cultivation enables phosphate extraction from inundated former agricultural soils

Azolla cultivation enables phosphate extraction from inundated former agricultural soils

•Azolla cultivation effectively extracts P from rewetted agricultural soils.•Azolla cultivation is possible on soils with a low porewater Fe:P ratio.•High porewater P concentrations facilitate high growth and P extraction rates.•Weekly to monthly harvesting of Azolla reduces surface water nutrient l...

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Published in:Water research (Oxford) Vol. 254; p. 121411
Main Authors: Vroom, RJE, Smolders, AJP, Van de Riet, BP, Lamers, LPM, Güngör, E, Krosse, S, Verheggen-Kleinheerenbrink, GM, Van der Wal, NR, Kosten, S
Format: Journal Article
Language:English
Published: England Elsevier Ltd 01-05-2024
Subjects:
Azolla filiculoides
Mesocosm
Phosphorus
Rehabilitation
Rewetting
Wetland
Phosphorus
Mesocosm
Rehabilitation
Rewetting
Wetland
Azolla filiculoides
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Summary:•Azolla cultivation effectively extracts P from rewetted agricultural soils.•Azolla cultivation is possible on soils with a low porewater Fe:P ratio.•High porewater P concentrations facilitate high growth and P extraction rates.•Weekly to monthly harvesting of Azolla reduces surface water nutrient levels. To combat the global loss of wetlands and their essential functions, the restoration and creation of wetlands is imperative. However, wetland development is challenging when soils have been in prolonged agricultural use, often resulting in a substantial nutrient legacy, especially of phosphorous (P). Inundating these soils typically leads to P mobilization, resulting in poor water quality and low biodiversity recovery. As a potential novel means to overcome this challenge, we tested whether cultivation of the floating fern Azolla filiculoides could simultaneously extract and recycle P, and provide a commercial product. Azolla has high growth rates due to the nitrogen fixing capacity of its microbiome and is capable of luxury consumption of P. Azolla cultivation may also accelerate soil P mobilization and subsequent extraction by causing surface water anoxia and the release of iron-bound P. To test this approach, we cultivated Azolla on 15 P-rich former agricultural soils in an indoor mesocosm experiment. Soils were inundated and either left unvegetated or inoculated with A. filiculoides during two 8-week cultivation periods. Biomass was harvested at different intervals (weekly/monthly/bimonthly) to investigate the effect of harvesting frequency on oxygen (O2) and nutrient dynamics. We found that Azolla attained high growth rates only on soils with high mobilization of labile P, as plant cover did not reduce surface water O2 concentrations in the first phase after inundation. This concurred with low porewater iron to P ratios (<10) and high porewater P concentrations. A. filiculoides cultivation substantially reduced surface water nutrient concentrations and extracted P at rates up to 122 kg ha−1 yr−1. We conclude that rapid P extraction by A. filiculoides cultivation is possible on soils rich in labile P, offering new perspectives for wetland rehabilitation. Additional field trials are recommended to investigate long-term feasibility, seasonal variations, and the influence of potential grazers and pathogens. [Display omitted]
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ISSN:0043-1354
1879-2448
DOI:10.1016/j.watres.2024.121411