| 1. |
- Iraguha, Gasore, et al.
(author)
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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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In: 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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Conference paper (other academic/artistic)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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| 2. |
- Mårtensson, Lennart, 1957-, et al.
(author)
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Biomass from wetlands and other valuable conservation areas as substrate for industrial biotechnology
- 2016
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In: The Ninth International Conference on the Establishment of Cooperation between Companies and Institutions in the Nordic Countries, the Baltic Sea Region, and the World. - 9789188357410
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Conference paper (peer-reviewed)abstract
- Biomass from wetlands has historically been an important resource, but today it is difficult to take advantage of this biomass, besides being used as feed on the farm. A very important goal is to find rational and economical viable way to make biogas from wetland biomass, including biomass from other conservation worthy areas of high biodiversity, such as roadsides harvested frequently. Moreover, the residues from biogas process used as bio-fertilizer to the fields, so that nitrogen and phosphorus is returned to the farm land. The biomass can be used for the production of biogas or for extracting valuable chemicals in bio refineries. These valuable chemicals may be potentially useful for making future plastic materials, i.e. bio plastics. Major focus will be on biogas technology, and above all, methods for the pretreatment of recalcitrant substrates such as biomass containing high levels of lignocelluloses, i.e., to make the material available to the biogas-producing bacteria. The work is based on an involvement of research in the areas of environmental engineering and landscape science and includes studies of biodiversity and water treatment function of the landscape. Finally, it is important to stress that mowing of wet meadows mostly will result in a better capacity of such meadows to retain nutrients from water passing through them. Wetland with wet meadows and similar vegetation types will be more efficient in cleaning water and thereby fight eutrophication in the recipient. Summing up, the main advantages using harvest hay (mowing) from wet meadows and roadside meadows as substrate for biotechnical industry are:•Raw material for bio plastics•Cheap and easy handled fertilizers to agriculture•Important for biodiversity•Better function of wetlands as nutrient traps fighting eutrophication of the sea
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| 3. |
- Pronoza, Lesya, et al.
(author)
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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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In: 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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Conference paper (other academic/artistic)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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