Exchange of mercury between atmosphere and vegetation under contaminated conditions

Lodenius, Martin; Tulisalo, Esa; Soltanpour-Gargari, A.

doi:10.1016/s0048-9697(02)00566-1

Cited by 82 publications

(50 citation statements)

References 12 publications

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“…We propose that factors other than that of soil contents may be playing an active role in the Hg cycle at Almadé n, such as extremely high concentrations of Hg atmos . It is known that plants do absorb Hg atmos via leaves (Patra & Sharma, 2000;Lodenius, Tulisalo, & Soltanpour-Gargari, 2003); however, do all plants have the same capacity for Hg atmos intake? Plant species do display contrasting behaviors: for example, Hg atmos intake by leaves of gramineous species such as Avena byzantina C Koch, Hordeum vulgare L. and Triticum aestivum L. is fivefold larger than that of corn (Zea mays L.) or sorghum (Sorghum sp.).…”

Section: Resultsmentioning

confidence: 99%

Mercury accumulation in soils and plants in the Almadén mining district, Spain: one of the most contaminated sites on Earth

Molina

Oyarzún

Esbrí

et al. 2006

Environ Geochem Health

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Although mercury (Hg) mining in the Almadén district ceased in May 2002, the consequences of 2000 years of mining in the district has resulted in the dissemination of Hg into the surrounding environment where it poses an evident risk to biota and human health. This risk needs to be properly evaluated. The uptake of Hg has been found to be plant-specific. To establish the different manners in which plants absorb Hg, we carried out a survey of Hg levels in the soils and plants in the most representative habitats of this Mediterranean area and found that the Hg concentrations varied greatly and were dependent on the sample being tested (0.13-2,695 microg g(-1) Hg). For example, the root samples had concentrations ranging from 0.06 (Oenanthe crocata, Rumex induratus) to 1095 (Polypogon monspeliensis) microg g(-1) Hg, while in the leaf samples, the range was from 0.16 (Cyperus longus) to 1278 (Polypogon monspeliensis) microg g(-1) Hg. There are four well-differentiated patterns of Hg uptake: (1) the rate of uptake is constant, independent of Hg concentration in the soil (e.g., Pistacia lentiscus, Quercus rotundifolia); (2) after an initial linear relationship between uptake and soil concentration, no further increase in Hg(plant) is observed (e.g., Asparagus acutifolius, Cistus ladanifer); (3) no increase in uptake is recorded until a threshold is surpassed, and thereafter a linear relationship between Hg(plant) and Hg(soil) is established (e.g., Rumex bucephalophorus, Cistus crispus); (4) there is no relationship between Hg(plant) and Hg(soil )(e.g., Oenanthe crocata and Cistus monspeliensis). Overall, the Hg concentrations found in plants from the Almadén district clearly reflect the importance of contamination processes throughout the study region.

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Section: Resultsmentioning

confidence: 99%

Mercury accumulation in soils and plants in the Almadén mining district, Spain: one of the most contaminated sites on Earth

Molina

Oyarzún

Esbrí

et al. 2006

Environ Geochem Health

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“…MeHg in soil was first absorbed by roots and then translocated to the above-ground parts (leaves and stalk, [9]). However, IHg accumulated in rice plants could mainly come from the atmosphere through leaf uptake, but not from soil [10][11], because the root surface, acting as IHg barrier, could inhibit the translocation of IHg through the root system to the aboveground parts, but could not inhibit MeHg transfer [12]. Meanwhile, recently rice leaves and stalk burial is being encouraged all over the world as an economical and environmentally friendly method to get rid of rice residuals.…”

mentioning

confidence: 99%

The Bioaccumulation and Migration of Inorganic Mercury and Methylmercury in the Rice Plants

Zhu¹,

Han²,

Wu³

2017

Pol. J. Environ. Stud.

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“…Both Rye grass (Lolium perenne) and moss (Sphagnum girgensohnii) have been shown to efficiently absorb atmospheric mercury at different temperatures. The sorption is strong with almost no losses even at high temperatures (up to +60°C) [15].…”

Section: Leavesmentioning

confidence: 96%

“…Terrestrial mosses have been used for monitoring metal emissions from road traffic [14] and industries [15,16]. Fernández et al [17] proposed a method using terrestrial mosses (Pseudoscleropodium purum) where it is possible to get a good picture of the metal distribution based on a limited number of samples.…”

Section: Terrestrial Mossesmentioning

confidence: 99%

Biomonitoring of air borne metal pollution

Lodenius

2014

WIT Transactions on Ecology and the Environment

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Mosses, lichens and vascular plants may be used for monitoring airborne pollution, e.g. wet and dry deposition of metals in polluted areas. Best results are achieved when using transplantation methods including exposure for a certain period of time. Spreading of metals around point sources can be followed with great accuracy. Often at least semi quantitative estimates of deposition can be made. Biomonitoring methods are cheap and efficient but relations to results achieved by technical methods should be evaluated in more detail.

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Exchange of mercury between atmosphere and vegetation under contaminated conditions

Cited by 82 publications

References 12 publications

Mercury accumulation in soils and plants in the Almadén mining district, Spain: one of the most contaminated sites on Earth

Mercury accumulation in soils and plants in the Almadén mining district, Spain: one of the most contaminated sites on Earth

The Bioaccumulation and Migration of Inorganic Mercury and Methylmercury in the Rice Plants

Biomonitoring of air borne metal pollution

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