| 1. |
- Haller, Henrik, 1977-, et al.
(författare)
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Bioaccumulation and translocation of field-weathered toxaphene and other persistent organic pollutants in three cultivars of amaranth (A. cruentus ‘R127 México’, A. cruentus ‘Don León’ y A. caudatus ‘CAC 48 Perú’) – A field study from former cotton fields in Chinandega, Nicaragua
- 2018
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Ingår i: Ecological Engineering. - : Elsevier BV. - 0925-8574 .- 1872-6992. ; 121, s. 65-71
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Tidskriftsartikel (refereegranskat)abstract
- Soils polluted by persistent organic pollutants threatens habitats for plants and animals as well as basic human needs such as food security and provision of potable water. Toxaphene is a persistent organic pollutant that was heavily used as a pesticide in Central America, Brazil, Soviet Union etc. until it was banned in 1993. The objective of this study was to determine the bioaccumulation and translocation characteristics of three different cultivars of amaranth in soils contaminated with field-weathered toxaphene and other POPs in former cotton fields in Chinandega, Nicaragua to identify safety issues for human consumption and/or potential for phytoremediation. The concentration of toxaphene and other POPs in the edible parts of the amaranth (leaves and seeds) exceeded the maximum residue level for human consumption established by the European Union for most of the tested compounds. Concentrations of toxaphene congeners and other POPs were found in all vegetative organs. Many substances were accumulated to concentrations more than 10 times higher than in the soil. Of the three cultivars, A. caudatus 'CAC48 Perú' and A. cruentus 'Don Leon' presented the highest average BAF. None of the 3 cultivars can be considered a panacea hyperaccumulator for either toxaphene alone or in conjunction with other POPs but since many agricultural soils comprise a range of different contaminants, the broad-spectrum bioaccumulating capacity of amaranth can make it an interesting candidate for phytoremediation.
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| 2. |
- Bergkvist, Lisa, et al.
(författare)
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Carbon Sequestration Potential f Agroforestry Systems For Phytoremediation In Chinandega, Nicaragua
- 2018
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Ingår i: Linnaeus Eco-Tech 2018. ; , s. 211-211
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Konferensbidrag (övrigt vetenskapligt/konstnärligt)abstract
- Greenhouse gases in the atmosphere have increased to earlier unrecorded levels, causing global climate change that increases GMT and threaten ecosystems and livelihoods. IPCC report suggest that agroforestry offers considerable carbon sequestration (c seq.) potential, especially for developing countries. The purpose of this study is to estimate the c seq. potential in different agroforestry systems suitable in Chinandega, Nicaragua - a deforested region where the ground is polluted by toxaphene and other POP:s. Three scenarios where studied; Shading system using Tectona grandis and Pogostemon cablin; Alley cropping using Erythrina poeppigiana and Ricinus communis and Silvopasture using Cordia alliodora and Brachiaria ruziziensis, the last scenario being divided into two subscenarios; unmanaged (grazed) and managed (harvested) grass. Calculations were performed using the modelling program CO2FIX v. 3.2, with a runtime of 100 years and assuming deforested area with no previous land use. Results show a significantly higher c seq. potential in Shading system (168/217 MgC/ha). Alley cropping yields 71 MgC/ha and Silvopasture results in 80/84 MgC/ha unmanaged and 65/70 MgC/ha managed. The higher number includes products from harvest. All scenarios show fluctuations over time due to thinning and harvesting practices. Phytoremediation potential of POPs has been shown in Ricinus communis and grass species. Soil c seq. is especially important to consider in longterm scenarios as this c seq. can be sustained over longer time. The inclusion of crop residue, the effect of grazing animals or changes in density of trees and crops and environmental fate of the toxic compounds need further assessment before considering large scale applications. Agroforestry practices could contribute to several benefits, including climate change mitigation and phytoremediation.
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| 3. |
- Kåresdotter, Elisie, et al.
(författare)
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Modeling the Carbon Sequestration Potential of Multifunctional Agroforestry-Based Phytoremediation (MAP) Systems in Chinandega, Nicaragua
- 2022
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Ingår i: Sustainability. - : MDPI AG. - 2071-1050. ; 14:9
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Tidskriftsartikel (refereegranskat)abstract
- Global sustainability challenges associated with increasing resource demands from a growing population call for resource-efficient land-use strategies that address multiple sustainability issues. Multifunctional agroforestry-based phytoremediation (MAP) is one such strategy that can simultaneously capture carbon, decontaminate soils, and provide diverse incomes for local farmers. Chinandega, Nicaragua, is a densely populated agricultural region with heavily polluted soils. Four different MAP systems scenarios relevant to Chinandega were created and carbon sequestration potentials were calculated using CO2FIX. All scenarios showed the potential to store significantly more carbon than conventional farming practices, ranging from 2.5 to 8.0 Mg CO2eq ha−1 yr−1. Overall, carbon sequestration in crops is relatively small, but results in increased soil organic carbon (SOC), especially in perennials, and the combination of crops and trees provide higher carbon sequestration rates than monoculture. Changes in SOC are crucial for long-term carbon sequestration, here ranging between 0.4 and 0.9 Mg C ha−1 yr−1, with the most given in scenario 4, an alley cropping system with pollarded trees with prunings used as green mulch. The adoption rate of multifunctional strategies providing both commodity and non-commodity outputs, such as carbon sequestration, would likely increase if phytoremediation is included. Well-designed MAP systems could help reduce land-use conflicts, provide healthier soil, act as climate change mitigation, and have positive impacts on local health and economies.
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| 4. |
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| 5. |
- Pronoza, Lesya, et al.
(författare)
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The use of an integrated planning guide to steer phytoremediation projects towards sustainability using the example of Amaranth (Amaranthus) to remediate toxaphene polluted soils in a tropical region
- 2016
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Ingår i: Proceedings of the Linnaeus Eco-Tech 2016 International Conference on Natural Sciences and Technologies for Waste and Wastewater Treatment, Remediation, Emissions Related to Climate, Environmental and Economic Effects.. - Kalmar : Linnaeus University. - 9789188357410
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Konferensbidrag (övrigt vetenskapligt/konstnärligt)abstract
- Soil pollution by pesticides is a serious problem, especially in developing countries where incentives are limited to remediate these soils. Toxaphene was a widely used insecticide during the 1950s – 1980s, but even after a total ban on its use in 2001 there are still many harmful consequences that can be observed. High levels of toxaphene on agriculture fields in Nicaragua continues to be a threat to local inhabitants and wildlife and to the surrounding ecosystems. Phytoremediation is one of the methods used for cleaning polluted soils. It requires growing plants in-situ and relies on their ability to absorb and accumulate or degrade toxic elements. Some advantages are environmental safety and cost-effectiveness.Amaranth (Amaranthus) was investigated as a primary candidate for the phytoremediation project. Beside this, some other plants, such as Cucurbita pepo, Spinacia oleracea, Medicago sativa, were reported to be able to successfully absorb common persistent organic pollutants. In addition, uptake mechanisms and patterns of distribution of toxic elements in plants were studied to determine further use of plants.To assess the viability and sustainability potential of implementing amaranth for phytoremediation, an Integrated Planning Guide (IPG) was used. The IPG uses a number of principles and concepts to provide guidelines for bioremediation actions. As a result, several conclusions and suggestions were produced, the most important being: amaranth has a potential for toxaphene uptake and has a high yield and historical significance; locally available poultry manure can be used as a fertilizer for amaranth; a monoculture should be avoided while growing amaranth; local community is the main driver of success and beneficiary of the project. Further research should be undertaken on this matter to improve the understanding of key factors for the success of the project.
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| 6. |
- Haller, Henrik, 1977-, et al.
(författare)
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Application of ecological engineering within the framework for strategic sustainable development for design of appropriate soil bioremediation technologies in marginalized regions
- 2018
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Ingår i: Journal of Cleaner Production. - : Elsevier. - 0959-6526 .- 1879-1786. ; 172, s. 2415-2424
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Tidskriftsartikel (refereegranskat)abstract
- This study explores a systematic strategy to design appropriate bioremediation projects for marginalized regions that have the potential to contribute to sustainable development in that region. Ecological Engineering (EE) is of particular value for the development of appropriate bioremediation technology for such regions but a stricter planning tool than provided by EE itself, is also needed when the goal of the project goes beyond remediation targets. The Framework for Strategic Sustainable Development (FSSD) applies basic principles for sustainability and includes a stepwise strategic planning mechanism for their application. The inclusion of EE within the FSSD may steer soil bioremediation projects in rural areas in developing countries and sparsely populated regions in industrialized countries towards sustainability. The utility of the approach was tested on two cases of soil pollution in marginalized regions: the Chinandega region in Nicaragua (pesticide polluted agricultural soil) and a former filling station (diesel polluted residual area) in Gäddede, northern Sweden. The study demonstrates how the inclusion of the EE key concepts within the FSSD may increase the utility of EE for strategic sustainable development within the region. No difficulties in terms of conflicting suggestions were found in the proposed integrated approach; the two tools were found to contribute on different aspects to provide support to project management and decision making.
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| 7. |
- Iraguha, Gasore, et al.
(författare)
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Using an integrated planning guide for the selection and design of a multi-process strategy for bioremediation of toxaphene and heavy metal contaminated soil in a tropical region
- 2016
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Ingår i: Proceedings of the Linnaeus Eco-Tech Conference on Natural Sciences and Technologies for Waste and Wastewater Treatment, Remediation, Emissions related to Climate, Environmental, and Economic Effects.. - : Linnaeus University. - 9789188357410
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Konferensbidrag (övrigt vetenskapligt/konstnärligt)abstract
- The application of pesticides and inappropriate soil management during intensive cotton farming in Chinandega, Nicaragua has left the soil with high residues of toxaphene and potentially several toxic metalloids and heavy metals from the overuse of mineral fertilizers. Most effective remediation approaches are relatively expensive and use technologies that are energy-intensive and hence not applicable in regions with low economic incentives for remediation. The selection of appropriate and low-cost approaches for soil remediation requires a structured and systematic process to ensure reliable outcomes with low environmental impact. The ideal situation is if such projects could contribute to a sustainable development in the region where the remediation is taking place. An Integrated Planning Guide which includes the key concepts of Ecological Engineering within the Framework for Strategic Sustainable Development was used in the identification and design of some applicable and efficient approaches for the clean-up of soil in Chinandega. This resulted in the design of a multi-process bioremediation strategy that meets the sustainability criteria of the Integrated Planning Guide and that has the potential to degrade toxaphene and remediate heavy metals and metalloids in the soil using Jatropha curcas L. for phytoremediation in combination with Bio-augmentation, biochar as a soil amendment, and the use of biochar and alginate as carriers of toxaphene degrading inocula.
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