Comparing the Efficiency of Sunflower, Marigold and Spinach Plants for Their Phytoextraction Ability of Zinc and Copper in Contaminated Soil

IF 1.4 Q3 AGRONOMY
Saubhagya Kumar Samal, Siba Prasad Datta, Debasis Golui, Md Basit Raza, Brahma Swaroop Dwivedi, Mahesh Chand Meena, Mahaveer Nogiya, Mahipal Choudhary, Punyavrat S. Pandey
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Abstract

Phytoextraction is a cost-effective technique to remediate contaminated soil. The efficiency of the phytoextraction process is limited by the slow growth, small biomass production of hyper-accumulator plants, and lower phytoavailability of contaminants in soil. The study is focused on comparing the efficiency of the three reported accumulator plants for phytoextraction of zinc (Zn) and copper (Cu) from contaminated soil and their effect on the bioavailability/toxicity of the elements after harvest. In a pot experiment, sunflower, marigold, and spinach were grown in Zn and Cu-contaminated soil. After harvest, the effect of phytoextraction on the distribution of Zn and Cu in various soil-solid phases was studied through a fractionation study as an indicator of bioavailability. The efficiency of phytoextraction was compared in terms of the metal uptake ability of the plants. The highest biomass yield of accumulator plants was obtained with marigold (30.1 g pot−1), followed by sunflower (16.3 g pot−1) and spinach (7.75 g pot−1). The concentrations of Zn and Cu in the three plants ranged from 58.0 to 222 mg kg−1 and 6.33 to 13.3 mg kg−1, respectively. In both the cases of Zn and Cu, sunflower was found superior to the other two plants in terms of phytoextraction of the metals from the contaminated soil. A fractionation study showed that in sunflower and marigold-grown soil, the carbonate bound fraction of Zn enriched water-soluble and exchangeable fraction of Zn, while in spinach-grown soil, the dissolved carbonate bound fraction of Zn enriched the organically bound fraction. Thus, it can be inferred that sunflowers and marigolds increased the bioavailability and toxicity of Zn and Cu more than that of spinach.

Abstract Image

向日葵、万寿菊和菠菜植物对污染土壤中锌和铜的植物提取能力比较
植物萃取是一种具有成本效益的污染土壤修复技术。植物萃取过程的效率受到超积累植物生长缓慢、生物量产量小以及土壤中污染物植物利用率较低的限制。本研究的重点是比较三种已报道的蓄积植物从污染土壤中植物萃取锌(Zn)和铜(Cu)的效率及其对收获后元素生物利用率/毒性的影响。在一项盆栽实验中,向日葵、万寿菊和菠菜生长在受锌和铜污染的土壤中。收获后,通过作为生物利用率指标的分馏研究,研究了植物萃取对锌和铜在不同土壤固相中分布的影响。根据植物的金属吸收能力比较了植物萃取的效率。万寿菊(30.1 克/盆-1)的累积植物生物量产量最高,其次是向日葵(16.3 克/盆-1)和菠菜(7.75 克/盆-1)。三种植物中的锌和铜浓度分别为 58.0 至 222 毫克/千克和 6.33 至 13.3 毫克/千克。就锌和铜而言,向日葵从污染土壤中植物萃取金属的能力优于其他两种植物。分馏研究表明,在向日葵和金盏花种植的土壤中,锌的碳酸盐结合部分富集了锌的水溶性和可交换部分,而在菠菜种植的土壤中,锌的溶解碳酸盐结合部分富集了有机结合部分。因此,可以推断向日葵和万寿菊比菠菜更能提高锌和铜的生物利用率和毒性。
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来源期刊
CiteScore
3.80
自引率
0.00%
发文量
24
期刊介绍: The main objective of this initiative is to promote agricultural research and development. The journal will publish high quality original research papers and critical reviews on emerging fields and concepts for providing future directions. The publications will include both applied and basic research covering the following disciplines of agricultural sciences: Genetic resources, genetics and breeding, biotechnology, physiology, biochemistry, management of biotic and abiotic stresses, and nutrition of field crops, horticultural crops, livestock and fishes; agricultural meteorology, environmental sciences, forestry and agro forestry, agronomy, soils and soil management, microbiology, water management, agricultural engineering and technology, agricultural policy, agricultural economics, food nutrition, agricultural statistics, and extension research; impact of climate change and the emerging technologies on agriculture, and the role of agricultural research and innovation for development.
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