Phytoremediation of Arsenic-Contaminated Soils Amended with Red Mud Combined with Phosphogypsum

Several industrial by-products may be used as amendments to reduce arsenic availability in contaminated areas, hence contributing to phytoremediation processes. This study was conducted aiming to evaluate red mud (RM) and a mixture containing 75% of RM + 25% of phosphogypsum (PG) (hereafter, RMPG) a...

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Published in	Water, air, and soil pollution Vol. 232; no. 10; p. 417
Main Authors	de Souza Costa, Enio Tarso, Lopes, Guilherme, Carvalho, Geila Santos, Penha, Henrique Gualberto Vilela, Curi, Nilton, Guilherme, Luiz Roberto Guimarães
Format	Journal Article
Language	English
Published	Cham Springer International Publishing 01.10.2021 Springer Springer Nature B.V
Subjects	air Arsenic Atmospheric Protection/Air Quality Control/Air Pollution Availability Bioremediation Calcium Chemical composition Clay Clay soils Climate Change/Climate Change Impacts Contamination Dry matter dry matter accumulation Earth and Environmental Science Electrical conductivity Electrical resistivity Environment Environmental monitoring Gypsum hydrogen Hydrogeology Leachates Limestone Mud Nutrients Organic matter pH effects Phosphogypsum Phytoremediation Plant resistance Plant roots Quartzipsamments Red mud roots Sandy soils Sodium Soil contamination Soil mixtures Soil pollution Soil properties Soil Science & Conservation Soils Sulfur Sulphur Toxicity Urochloa brizantha water Water Quality/Water Pollution Trace element Amendment By-product Remediation Reuse
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Abstract	Several industrial by-products may be used as amendments to reduce arsenic availability in contaminated areas, hence contributing to phytoremediation processes. This study was conducted aiming to evaluate red mud (RM) and a mixture containing 75% of RM + 25% of phosphogypsum (PG) (hereafter, RMPG) as amendments in arsenic-contaminated soils presenting distinct properties, like clay and organic matter content and chemical composition. Two contrasting soils were artificially contaminated with 150 mg dm 3 of arsenic and after that cultivated with Urochloa brizantha . The experiment was carried out using a Typic Dystrudox (LV, 750 g kg −1 clay) and a Typic Quartzipsamment (RQ, 70 g kg −1 clay), with the following RM and RMPG rates: 0, 0.5, 1.0, and 2.0% (w/v). Also, limestone was tested as an additional amendment for comparison. Hydrogen potential (pH), electrical conductivity (EC), sodium, and arsenic concentrations were analyzed on leachates, and the dry matter production of Urochloa brizantha and arsenic concentration in plant root and shoot dry matter were also recorded. The amendments increased pH, EC, and sodium concentration and the addition of RMPG decreased the arsenic concentration on leachates. RMPG increased plant dry matter production and decreased arsenic concentration in the plant’s shoot. The plant resistance to arsenic contamination was influenced by soil properties, with arsenic toxicity being more evident in the sandy soil (RQ) compared with the clayey soil (LV). The mixture (RMPG) has shown to be an advantageous amendment since, besides decreasing arsenic availability, it also furnishes the nutrients calcium and sulfur from the PG. Graphical abstract
AbstractList	Several industrial by-products may be used as amendments to reduce arsenic availability in contaminated areas, hence contributing to phytoremediation processes. This study was conducted aiming to evaluate red mud (RM) and a mixture containing 75% of RM + 25% of phosphogypsum (PG) (hereafter, RMPG) as amendments in arsenic-contaminated soils presenting distinct properties, like clay and organic matter content and chemical composition. Two contrasting soils were artificially contaminated with 150 mg dm3 of arsenic and after that cultivated with Urochloa brizantha. The experiment was carried out using a Typic Dystrudox (LV, 750 g kg−1 clay) and a Typic Quartzipsamment (RQ, 70 g kg−1 clay), with the following RM and RMPG rates: 0, 0.5, 1.0, and 2.0% (w/v). Also, limestone was tested as an additional amendment for comparison. Hydrogen potential (pH), electrical conductivity (EC), sodium, and arsenic concentrations were analyzed on leachates, and the dry matter production of Urochloa brizantha and arsenic concentration in plant root and shoot dry matter were also recorded. The amendments increased pH, EC, and sodium concentration and the addition of RMPG decreased the arsenic concentration on leachates. RMPG increased plant dry matter production and decreased arsenic concentration in the plant’s shoot. The plant resistance to arsenic contamination was influenced by soil properties, with arsenic toxicity being more evident in the sandy soil (RQ) compared with the clayey soil (LV). The mixture (RMPG) has shown to be an advantageous amendment since, besides decreasing arsenic availability, it also furnishes the nutrients calcium and sulfur from the PG. Several industrial by-products may be used as amendments to reduce arsenic availability in contaminated areas, hence contributing to phytoremediation processes. This study was conducted aiming to evaluate red mud (RM) and a mixture containing 75% of RM + 25% of phosphogypsum (PG) (hereafter, RMPG) as amendments in arsenic-contaminated soils presenting distinct properties, like clay and organic matter content and chemical composition. Two contrasting soils were artificially contaminated with 150 mg dm 3 of arsenic and after that cultivated with Urochloa brizantha . The experiment was carried out using a Typic Dystrudox (LV, 750 g kg −1 clay) and a Typic Quartzipsamment (RQ, 70 g kg −1 clay), with the following RM and RMPG rates: 0, 0.5, 1.0, and 2.0% (w/v). Also, limestone was tested as an additional amendment for comparison. Hydrogen potential (pH), electrical conductivity (EC), sodium, and arsenic concentrations were analyzed on leachates, and the dry matter production of Urochloa brizantha and arsenic concentration in plant root and shoot dry matter were also recorded. The amendments increased pH, EC, and sodium concentration and the addition of RMPG decreased the arsenic concentration on leachates. RMPG increased plant dry matter production and decreased arsenic concentration in the plant’s shoot. The plant resistance to arsenic contamination was influenced by soil properties, with arsenic toxicity being more evident in the sandy soil (RQ) compared with the clayey soil (LV). The mixture (RMPG) has shown to be an advantageous amendment since, besides decreasing arsenic availability, it also furnishes the nutrients calcium and sulfur from the PG. Graphical abstract Several industrial by-products may be used as amendments to reduce arsenic availability in contaminated areas, hence contributing to phytoremediation processes. This study was conducted aiming to evaluate red mud (RM) and a mixture containing 75% of RM + 25% of phosphogypsum (PG) (hereafter, RMPG) as amendments in arsenic-contaminated soils presenting distinct properties, like clay and organic matter content and chemical composition. Two contrasting soils were artificially contaminated with 150 mg dm.sup.3 of arsenic and after that cultivated with Urochloa brizantha. The experiment was carried out using a Typic Dystrudox (LV, 750 g kg.sup.-1 clay) and a Typic Quartzipsamment (RQ, 70 g kg.sup.-1 clay), with the following RM and RMPG rates: 0, 0.5, 1.0, and 2.0% (w/v). Also, limestone was tested as an additional amendment for comparison. Hydrogen potential (pH), electrical conductivity (EC), sodium, and arsenic concentrations were analyzed on leachates, and the dry matter production of Urochloa brizantha and arsenic concentration in plant root and shoot dry matter were also recorded. The amendments increased pH, EC, and sodium concentration and the addition of RMPG decreased the arsenic concentration on leachates. RMPG increased plant dry matter production and decreased arsenic concentration in the plant's shoot. The plant resistance to arsenic contamination was influenced by soil properties, with arsenic toxicity being more evident in the sandy soil (RQ) compared with the clayey soil (LV). The mixture (RMPG) has shown to be an advantageous amendment since, besides decreasing arsenic availability, it also furnishes the nutrients calcium and sulfur from the PG. Graphical abstract Several industrial by-products may be used as amendments to reduce arsenic availability in contaminated areas, hence contributing to phytoremediation processes. This study was conducted aiming to evaluate red mud (RM) and a mixture containing 75% of RM + 25% of phosphogypsum (PG) (hereafter, RMPG) as amendments in arsenic-contaminated soils presenting distinct properties, like clay and organic matter content and chemical composition. Two contrasting soils were artificially contaminated with 150 mg dm³ of arsenic and after that cultivated with Urochloa brizantha. The experiment was carried out using a Typic Dystrudox (LV, 750 g kg⁻¹ clay) and a Typic Quartzipsamment (RQ, 70 g kg⁻¹ clay), with the following RM and RMPG rates: 0, 0.5, 1.0, and 2.0% (w/v). Also, limestone was tested as an additional amendment for comparison. Hydrogen potential (pH), electrical conductivity (EC), sodium, and arsenic concentrations were analyzed on leachates, and the dry matter production of Urochloa brizantha and arsenic concentration in plant root and shoot dry matter were also recorded. The amendments increased pH, EC, and sodium concentration and the addition of RMPG decreased the arsenic concentration on leachates. RMPG increased plant dry matter production and decreased arsenic concentration in the plant’s shoot. The plant resistance to arsenic contamination was influenced by soil properties, with arsenic toxicity being more evident in the sandy soil (RQ) compared with the clayey soil (LV). The mixture (RMPG) has shown to be an advantageous amendment since, besides decreasing arsenic availability, it also furnishes the nutrients calcium and sulfur from the PG.
ArticleNumber	417
Audience	Academic
Author	Carvalho, Geila Santos Lopes, Guilherme Guilherme, Luiz Roberto Guimarães de Souza Costa, Enio Tarso Penha, Henrique Gualberto Vilela Curi, Nilton
Author_xml	– sequence: 1 givenname: Enio Tarso orcidid: 0000-0002-5655-7583 surname: de Souza Costa fullname: de Souza Costa, Enio Tarso email: eniotsc@gmail.com organization: Institute of Agricultural Sciences, Federal University of Uberlândia (UFU), Monte Carmelo Campus – sequence: 2 givenname: Guilherme orcidid: 0000-0002-7898-798X surname: Lopes fullname: Lopes, Guilherme organization: Department of Soil Science, School of Agricultural Sciences, Federal University of Lavras (UFLA) – sequence: 3 givenname: Geila Santos orcidid: 0000-0002-2437-1186 surname: Carvalho fullname: Carvalho, Geila Santos organization: Department of Soil Science, School of Agricultural Sciences, Federal University of Lavras (UFLA) – sequence: 4 givenname: Henrique Gualberto Vilela orcidid: 0000-0003-1574-5649 surname: Penha fullname: Penha, Henrique Gualberto Vilela organization: Federal Institute of Education, Science, and Technology of Triângulo Mineiro (IFTM), Uberlândia Campus – sequence: 5 givenname: Nilton surname: Curi fullname: Curi, Nilton organization: Department of Soil Science, School of Agricultural Sciences, Federal University of Lavras (UFLA) – sequence: 6 givenname: Luiz Roberto Guimarães orcidid: 0000-0002-5387-6028 surname: Guilherme fullname: Guilherme, Luiz Roberto Guimarães organization: Department of Soil Science, School of Agricultural Sciences, Federal University of Lavras (UFLA)
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SubjectTerms	air Arsenic Atmospheric Protection/Air Quality Control/Air Pollution Availability Bioremediation Calcium Chemical composition Clay Clay soils Climate Change/Climate Change Impacts Contamination Dry matter dry matter accumulation Earth and Environmental Science Electrical conductivity Electrical resistivity Environment Environmental monitoring Gypsum hydrogen Hydrogeology Leachates Limestone Mud Nutrients Organic matter pH effects Phosphogypsum Phytoremediation Plant resistance Plant roots Quartzipsamments Red mud roots Sandy soils Sodium Soil contamination Soil mixtures Soil pollution Soil properties Soil Science & Conservation Soils Sulfur Sulphur Toxicity Urochloa brizantha water Water Quality/Water Pollution
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Title	Phytoremediation of Arsenic-Contaminated Soils Amended with Red Mud Combined with Phosphogypsum
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