Soil remediation – mycolab.ai

Optimizing bioremediation techniques for soil decontamination in a linguistic intuitionistic fuzzy framework

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This research develops mathematical tools to help experts choose the best method for cleaning contaminated soil using living organisms. The study presents new fuzzy logic operators that can handle both numerical and linguistic information, making decisions more understandable to humans. When applied to a contaminated industrial site, the method identified bioaugmentation (adding beneficial microorganisms) as the most effective cleanup approach among four options tested.

Dosage of Sulfidized Nano Zero-Valent Iron, Soil Moisture and pH Influences on Fraction of Arsenic and Cadmium in Contaminated Paddy Soil

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This study examines using tiny iron particles coated with sulfur to clean rice paddy soils contaminated with arsenic and cadmium. The researchers tested different amounts of this material, soil moisture levels, and soil acidity to find the best conditions for trapping these harmful metals in the soil so rice plants cannot absorb them. They found that using a moderate amount of the material works best and that keeping the soil wet helps prevent the metals from becoming available to plants.

Functional genomic analysis of Bacillus cereus BC4 strain for chromium remediation in contaminated soil

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Scientists discovered a bacterium called Bacillus cereus BC4 that can remove dangerous chromium from contaminated soil very effectively. By sequencing the bacteria’s genes, they found specific proteins that help it break down and transport chromium, converting the toxic form into a less harmful version. This research could help clean up polluted soils and restore damaged ecosystems, offering a natural and sustainable approach to environmental cleanup.

Actinorhizal plants and Frankiaceae: The overlooked future of phytoremediation

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Actinorhizal plants are special trees and shrubs that team up with beneficial bacteria called Frankiaceae to clean up polluted and degraded soils. This natural partnership helps these plants survive harsh conditions like salty or heavy metal-contaminated soil while also cleaning up the environment. The bacteria help the plants by providing essential nitrogen and improving their ability to tolerate pollution, making them an inexpensive and sustainable solution for restoring degraded farmland.

Current state of the heavy metal pollution, microbial diversity, and bioremediation experiments around the Qixia Mountain lead–zinc mine in Nanjing, China

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A lead-zinc mine in Nanjing, China has contaminated surrounding soils with dangerous heavy metals like lead, zinc, and cadmium over 70 years of operation. Researchers discovered that combining amaranth plants with a beneficial bacterium called Bacillus velezensis dramatically reduced heavy metal pollution in soil, lowering pollution levels from severely contaminated to acceptable levels. This plant-microorganism approach also improved plant growth while reducing heavy metal uptake in the edible parts of crops, offering a practical solution to make farmland around mines safer for growing food.

A Review on Remediation Technology and the Remediation Evaluation of Heavy Metal-Contaminated Soils

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Heavy metals from industrial activities, mining, and vehicle emissions contaminate agricultural soils and pose health risks to humans through the food chain. This review summarizes different methods to clean contaminated soils, ranging from physical removal to using plants and microorganisms to absorb metals. The most promising approaches combine multiple techniques and use biological methods like planting metal-accumulating plants, which are cheaper and less damaging to soil ecology than traditional chemical or thermal treatments.

Screening, identification, metabolic pathway of di-n-butyl phthalate degrading Priestia megaterium P-7 isolated from long-term film mulched cotton field soil in Xinjiang

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This research identifies a special bacterium called Priestia megaterium P-7 that can efficiently break down di-n-butyl phthalate (DBP), a harmful plastic chemical that accumulates in cotton field soils. Scientists found that this bacterium can completely remove DBP from contaminated soil within 20 hours under optimal conditions. By studying the bacterium’s genes and metabolism, they discovered the specific enzymes and pathways it uses to degrade DBP into harmless compounds. This finding offers a practical biological solution for cleaning up contaminated agricultural soils, particularly in Xinjiang where plastic film mulching is widely used in cotton farming.

Scoping Review on Mitigating the Silent Threat of Toxic Industrial Waste: Eco-Rituals Strategies for Remediation and Ecosystem Restoration

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This review examines how industrial waste contaminates soil and water through heavy metals and chemicals, harming ecosystems and human health through food chain contamination. The study shows that pollutants like cadmium and lead kill aquatic life, reduce soil fertility, and disrupt beneficial soil microorganisms. The review recommends solutions including cleaner manufacturing practices, advanced wastewater treatment, and eco-friendly methods like using plants to absorb contaminants.

Phytoremediation of Heavy Metal-Contaminated Soil Using Drought-Adapted Sweet Sorghum (Sorghum bicolor L.) in Arid Regions of Kazakhstan

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Researchers found that sweet sorghum, a drought-tolerant crop, can effectively clean soil contaminated with toxic metals in Kazakhstan’s dry regions. By carefully selecting genotypes that were both adapted to harsh conditions and showed strong growth in laboratory tests, they demonstrated that the plants accumulate lead, cadmium, and cobalt primarily in their roots, making them safe for harvesting. This plant-based approach offers an affordable and environmentally friendly alternative to expensive traditional soil cleanup methods.

Mycoremediation of Petroleum-Contaminated Soil Using Native Ganoderma and Trametes Strains from the Ecuadorian Amazon

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Oil spills in the Amazon rainforest cause serious environmental and health problems. Scientists discovered that certain mushroom fungi found in Ecuador can break down petroleum pollutants in soil more effectively than natural processes. In lab tests, five native fungal strains removed over 96% of petroleum hydrocarbons from contaminated soil in just 60 days, offering a promising natural solution for cleaning up oil-polluted areas.

therapeutic action: Soil remediation