Phosphorus retention and fractionation in an eutrophic wetland: A one-year mesocosms experiment under fluctuating flooding conditions

María Del Carmen Tercero; José Álvarez-Rogel; Héctor Miguel Conesa; Isabel Párraga-Aguado; María Nazaret González-Alcaraz

doi:10.1016/j.jenvman.2016.12.060

Phosphorus retention and fractionation in an eutrophic wetland: A one-year mesocosms experiment under fluctuating flooding conditions

J Environ Manage. 2017 Apr 1:190:197-207. doi: 10.1016/j.jenvman.2016.12.060.

Authors

María Del Carmen Tercero¹, José Álvarez-Rogel¹, Héctor Miguel Conesa¹, Isabel Párraga-Aguado¹, María Nazaret González-Alcaraz²

Affiliations

¹ Departamento de Ciencia y Tecnología Agraria, Escuela Técnica Superior de Ingeniería Agronómica, Universidad Politécnica de Cartagena, Paseo Alfonso XIII 48, Cartagena, 30203, Murcia, Spain.
² Departamento de Ciencia y Tecnología Agraria, Escuela Técnica Superior de Ingeniería Agronómica, Universidad Politécnica de Cartagena, Paseo Alfonso XIII 48, Cartagena, 30203, Murcia, Spain. Electronic address: nazaret.gonzalez@upct.es.

PMID: 28049089
DOI: 10.1016/j.jenvman.2016.12.060

Abstract

This study aimed to evaluate the response of salt marshes to pulses of PO₄^3--enriched water, with and without the presence of Phragmites australis. A one-year mesocosms experiment was performed in simulated soil profiles (fine-textured surface layers and sandy subsurface layers) from a coastal salt marsh of the Mar Menor lagoon under alternating flooding-drying conditions with eutrophic water, under low (1.95 mg L^-1 P-PO₄^3-) and high (19.5 mg L^-1 P-PO₄^3-) P load, and with the presence/absence of Phragmites. The PO₄^3- concentrations in soil porewater and drainage water were regularly measured, and P accumulated in soils (including a fractionation procedure) and plants (roots, rhizomes, stems and leaves) were analyzed. The experimental mesocosms were highly effective in the removal of P from the eutrophic flooding water (>90% reduction of the P added to the system both in the soil pore water and drainage water), regardless of the nutrient load, the season of the year and the presence/absence of Phragmites. The soil was the main sink of the P added to the system, while Phragmites had a minor role in P removal. The biomass of Phragmites accumulated ∼27% of the P added with the flooding water in the treatment with water of low P load while ∼12% of P in that of high P load; the rhizomes were the organs that contributed the most (∼67-72% of the total P retained by the plants). Ca/Mg compounds were the main contributors to the retention of P in the soil compartment, especially in the fine-textured surface soil layers (∼34-53% of the total P in the soil was present in this fraction). Phragmites favored the retention of P onto metal oxides (∼12% increase of the P retained in the metal oxides fraction in the treatment with water of high P load). Hence, the use of constructed wetlands to ameliorate the negative impacts of P-enriched waters in the Mar Menor lagoon and similar areas is recommended. We propose the incorporation of fine-textured carbonated materials, with high content of Ca/Mg compounds, and the use of Phragmites to favor the retention of P by these systems.

Keywords: Green filters; Mar Menor lagoon; Phosphorus dynamics; Phragmites australis; Wetting-drying cycles.

MeSH terms

Biomass
Eutrophication
Floods
Oxides / chemistry
Oxides / metabolism
Phosphates / chemistry
Phosphates / metabolism
Phosphorus* / analysis
Phosphorus* / chemistry
Phosphorus* / metabolism
Plant Leaves / metabolism
Plant Roots
Plant Stems / metabolism
Poaceae / metabolism
Rhizome / metabolism
Seasons
Soil / chemistry
Spain
Water / chemistry
Wetlands*

Substances

Oxides
Phosphates
Soil
Water
Phosphorus