Industrial processes like mining, smelting, and electronics manufacturing generate significant environmental waste, contaminating soil with toxic metals detrimental to plant and animal life..
The removal of contaminated soil can be complex and costly. Traditional soil disposal methods, such as landfilling, often lead to diminished soil quality. To address these challenges, scientists and agricultural experts are exploring innovative plant-based solutions for effective soil remediation. One prevalent method involves the use of metal-absorbing plants, known as phytoremediation. Enhancing these plants with growth-promoting microorganisms boosts root development and nutrient uptake, thereby fostering better plant growth.
In addition to phytoremediation, farmers utilize treatments produced by pyrolyzing organic matter under low-oxygen conditions, referred to as biochar. Biochar effectively binds heavy metals present in the soil, thus reducing their toxicity. However, research on the combined impact of microorganisms and biochar for soil remediation remains limited.
A research team in Portugal conducted experiments to explore whether the phytoremediation effectiveness of biochar could be enhanced through the addition of specific microorganisms. They investigated the effects of two microbial strains: the bacteria Pseudomonas liatans EDP28 and the fungi Rhizoglomus irregulare, both recognized for their plant growth-promoting qualities.
The research aimed to determine if treating the soil could mitigate copper contamination and enhance sunflower growth in areas impacted by mining activities. The average copper concentration in harvested soil from Portuguese mines was found to be 1,080 milligrams per kilogram (mg/kg), significantly exceeding the U.S. Environmental Protection Agency’s recommended range of 100 to 300 mg/kg.
The experimental setup took place in a controlled greenhouse environment. Researchers tested three microbial treatments: P. Reactance bacteria, R. Irregular fungi, and a mixture of both. They combined contaminated mine soil with each microbial treatment and introduced five sunflower seedlings per pot, along with varying doses of biochar at 0%, 2.5%, and 5% by weight. This resulted in a total of 12 experimental treatments, including controls without biochar or microorganisms.
After a 12-week growth period, the researchers assessed sunflower growth by measuring chlorophyll levels, the green pigment essential for photosynthesis. Using specialized equipment, they shined red and infrared light through the leaves and discovered that while adding biochar did not significantly alter chlorophyll levels, the microbial inoculum enhanced chlorophyll content and subsequently improved photosynthetic capacity.
Further analysis included measuring the lengths of roots and shoots, followed by drying the plants to calculate their total dry weight. Results indicated that the addition of biochar negatively impacted plant growth; sunflowers treated with 2.5% and 5% biochar exhibited 22% and 26% shorter shoots, along with 46% and 49% less shoot mass compared to controls.
Conversely, microbial inoculants, particularly the combination of bacteria and fungi, mitigated the detrimental effects of biochar on plant growth. When compared to sunflowers grown without microorganisms, the mixed inoculum enhanced shoot length by 48% and 45% and boosted shoot dry biomass by 122% and 137% at 2.5% and 5% biochar treatments, respectively.
Copper concentrations were analyzed by dissolving the soil, plant roots, and shoots in water and acid, followed by evaporating the sample using flame atomic absorption spectroscopy..
The findings revealed that copper levels were consistently higher in the roots than in the shoots across all treatments. Biochar application increased root copper concentration by an average of 38% compared to control plants lacking biochar. This finding contradicts previous studies suggesting that biochar impedes metal uptake in plants.
However, microorganisms displayed inconsistent effects on copper levels; the mixed inoculum increased root copper concentrations by 51% in the 2.5% biochar treatment, but did not influence copper levels in the 5% biochar treatment.
In conclusion, the researchers posited that biochar enhances the phytoremediation capabilities of sunflowers by increasing copper accumulation in the roots, albeit resulting in reduced sunflower growth. Conversely, the presence of microbes boosts chlorophyll content, significantly enhancing both plant growth and photosynthetic activity. The research team advocates for future large-scale field studies involving microbial inoculants and biochar to explore their practical applications in real-world soil remediation efforts.
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Source: sciworthy.com
