Trace metal concentrations and their transfer from sediment to leaves of four common aquatic macrophytes

Łojko, Renata; Polechońska, Ludmiła; Klink, Agnieszka; Kosiba, Piotr

doi:10.1007/s11356-015-4641-1

Cited by 16 publications

(15 citation statements)

References 31 publications

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“…RCG could be used for phytoremediation in terrestrial and aquatic environments (e.g. Lojko et al, 2015) and black wormwood (Artemisia vulgaris L., 310.6 mg/g DM). At RCG, the hyperaccumulation in this study was predicted for nickel and manganese (here even high).…”

Section: Phytoremediation Potentialmentioning

confidence: 99%

Reed canary grass (Phalaris arundinacea L.) as a promising energy crop

Usťak¹,

Šinko²,

Muňoz³

2019

JCEA

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Reed canary grass (Phalaris arundinacea L.) is a perennial fast-growing C 3 plant belongs to family Poaceae with an early season growth, a wide physiological tolerance and with large possibilities of utilization. Recently, the use for bioenergy has become very perspective mainly because its high yield (5-10 t dry matter ha/year) and very good properties for combustion. The mean calorific value is about 16-18 MJ/kg dry matter. It can be usually harvested twice a year at lower cultivation inputs and shows the ability to grow in wide range of soil conditions including on land, which is not appropriate for other agricultural purposes. It has also the potential for different industrial applications, for example for biogas, ethanol, pulp and paper production, or for the production of chemical raw materials, too. The cultivation area rapidly increases, mainly in North Europe, where it is cultivated on thousands of hectares. The cultivation for energy or other industrial purposes has also benefits to the environment because of low intensity on agricultural management, supporting biodiversity and soil preservation against erosion.

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Section: Phytoremediation Potentialmentioning

confidence: 99%

Reed canary grass (Phalaris arundinacea L.) as a promising energy crop

Usťak¹,

Šinko²,

Muňoz³

2019

JCEA

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“…In the case of the level of BCF<10, they are difficult to characterize since both bottom sediments and inflow pollutants can constitute the source of chemical elements [Chiarenzelli et al 2001]. Different patterns in the accumulation of chemical elements between plants organs and bottom sediments were found in many studies [Bose et al 2008, Sasmaz et al 2009, Zang et al 2009, Qian et al 2012, Łojko et al 2015. The translocation factor (TF) generally showed the mobility of chemical elements from roots to rhizomes and from rhizomes to leaves.…”

Section: Bioconcentration and Translocation Factorsmentioning

confidence: 99%

Accumulation of Chemical Elements by Organs of Sparganium Erectum L. And Their Potential Use in Phytoremediation Process

Parzych¹

2016

J. Ecol. Eng.

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“…The accumulation of metals by macrophytes is affected by the concentrations of metals in water and sediments and by the speciation of metals such as free ions and humic complexes (Kramer, 2010). Aquatic macrophytes are predominant organisms in lake ecosystems that, in comparison with other plant species, can absorb metals through their roots as well as through their leaves (Twardowska and Kyziol, 2003;Lojko et al,2015). Hydrocotyle ranunculoides, as well as the cattail (Scirpus californicus) in the study area, serves as animal feed.…”

Section: Introductionmentioning

confidence: 99%

Metal phytosorption potential of Hydrocotyle ranunculoides for mitigation of water pollution in high Andean wetlands of Peru

et al. 2020

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The phytosorption potential of metals of Hydrocotyle ranunculoides was evaluated for the mitigation of water pollution in the high Andean wetlands of Peru. The plants were selected from 10 wetland sites in the community of Pomachaca- Tarma and were washed with potable water, dried, ground, weighed, chemically digested and read with Varian AA 240 atomic absorption equipment. The plant showed copper concentrations in the root (12.08 ± 1.67 mg/kg) greater than the stem (7.37 ± 1.00 mg/kg), followed by the leaves (7.37 ± 1.56 mg/kg). Lead concentration in the root was 0.228 ± 0.711 mg/kg, but was not found in the stem or leaves. The highest zinc concentration was in the root (67.52 ± 12.57 mg/kg) to the stem (53.30 ± 0.61 mg/kg), followed by the leaves (43.99 ± 8.49 mg/kg). Finally, iron was higher in the root (5571.28 ± 693.94 mg/kg) than in the leaves (342.76 ±122.09 mg/kg), followed by the stem (291.94 ± 54.84 mg/kg). Surrounding water had pH between 7.2 and 7.6; no copper and lead were found, zinc was 0.005 ± 0.012 mg/L and iron was 0.009± 0.007 mg/L. In the sediment, copper was 26.12 ± 0.65 mg/kg, lead 28.25 ± 2.41 mg/kg, zinc 85.98 ± 11.38 mg/kg and iron 26111.89 ± 614.37 mg/kg. These results indicate that this plant absorbs metals in the order of Fe>Zn>Cu>Pb and is an alternative for the development of phytotechnology, oriented to the treatment of effluents with metals that contaminate water in wetlands.

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Trace metal concentrations and their transfer from sediment to leaves of four common aquatic macrophytes

Cited by 16 publications

References 31 publications

Reed canary grass (Phalaris arundinacea L.) as a promising energy crop

Reed canary grass (Phalaris arundinacea L.) as a promising energy crop

Accumulation of Chemical Elements by Organs of Sparganium Erectum L. And Their Potential Use in Phytoremediation Process

Metal phytosorption potential of Hydrocotyle ranunculoides for mitigation of water pollution in high Andean wetlands of Peru

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