Major aspects of the mercury cycle in the Negro River Basin, Amazon

Silva, Gilmar Silvério da; Bisinoti, Márcia Cristina; Fadini, Pedro Sérgio; Magarelli, Gabriela; Jardim, Wilson F.; Fostier, Anne Hélène

doi:10.1590/S0103-50532009000600019

Abstracts

Despite the low level of industrial activity and human density, Hg concentration in the Negro River basin is relatively high. Soil enriched with naturally high Hg concentrations and atmospheric deposition are the main sources of the metal in this watershed. Differences between invasive and evasive fluxes at the water/air and soil/air interfaces indicate Hg accumulation in the basin at a rate of 39.9 t y-1. The type of soil, which is the main source of mercury for the water bodies, the hydrological cycle with floods and dry periods, act markedly on the water redox chemistry. A complex interaction between many seasonable variables such as solar intensity, water pH, age of the naturally occurring organic matter and the hydrological cycle alter the redox characteristics of these black water bodies, thus markedly affecting the consumption of Hg0 and the degradation of methylmercury present in the water. Although methylation is favored in black waters, photodegradation counterpoints this formation, thus regulating the methylmercury burden in the water column.

Negro River; mercury fluxes; mercury species; black waters

Embora com pouca atividade humana, as concentrações de Hg na bacia do Rio Negro são relativamente altas. A presença natural de Hg em solos e a deposição atmosférica são as principais fontes deste metal. O balanço entre fluxos invasivos e evasivos sugerem o seu acúmulo no interior da bacia em 39.9 t ano-1. O tipo de solo, fonte de metal para os rios, e o ciclo hidrológico com períodos de cheia e seca atuam sobre a química redox das águas. A conjunção sazonal de fatores como a natureza da matéria orgânica, pH ácido e radiação solar permitem que as águas pretas oscilem de redutora a oxidante, onde, por sua vez, ocorre o consumo de Hg0 e degradação do metilmercúrio. Deste modo, o fluxo do mercúrio pode ser invasivo ou evasivo. Embora a metilação seja mais favorecida em águas pretas, a fotodegradação do metilmercúrio se contrapõe ao seu acúmulo, contribuindo para regular o estoque deste composto na coluna água.

ARTICLE

Major aspects of the mercury cycle in the Negro River Basin, Amazon

Gilmar Silvério da Silva^I; Márcia Cristina Bisinoti^II; Pedro Sérgio Fadini^III; Gabriela Magarelli^IV; Wilson F. JardimV, ^* * e-mail: wfjardim@iqm.unicamp.br ; Anne Hélène Fostier^V

^IInstituto Federal de Educação, Ciência e Tecnologia do Maranhão, Departamento Acadêmico de Química, 65025-000 São Luís-MA, Brazil

^IIInstituto de Biociências, Letras e Ciências Exatas, Universidade Estadual Paulista 'Júlio de Mesquita Filho', 15054-000 São José do Rio Preto-SP, Brazil

^IIIDepartamento de Química, Universidade Federal de São Carlos, CP 676, 13565-905 São Carlos-SP, Brazil

^IVEmpresa Brasileira de Pesquisa Agropecuária, Embrapa Recursos Genéticos e Biotecnologia, Núcleo de Segurança Biológica, CP 02372, 70770-900 Brasilia-DF, Brazil

^VInstituto de Química, Universidade Estadual de Campinas, CP 6154, 13083-970 Campinas-SP, Brazil

ABSTRACT

Despite the low level of industrial activity and human density, Hg concentration in the Negro River basin is relatively high. Soil enriched with naturally high Hg concentrations and atmospheric deposition are the main sources of the metal in this watershed. Differences between invasive and evasive fluxes at the water/air and soil/air interfaces indicate Hg accumulation in the basin at a rate of 39.9 t y^-1. The type of soil, which is the main source of mercury for the water bodies, the hydrological cycle with floods and dry periods, act markedly on the water redox chemistry. A complex interaction between many seasonable variables such as solar intensity, water pH, age of the naturally occurring organic matter and the hydrological cycle alter the redox characteristics of these black water bodies, thus markedly affecting the consumption of Hg⁰ and the degradation of methylmercury present in the water. Although methylation is favored in black waters, photodegradation counterpoints this formation, thus regulating the methylmercury burden in the water column.

Keywords: Negro River, mercury fluxes, mercury species, black waters

RESUMO

Embora com pouca atividade humana, as concentrações de Hg na bacia do Rio Negro são relativamente altas. A presença natural de Hg em solos e a deposição atmosférica são as principais fontes deste metal. O balanço entre fluxos invasivos e evasivos sugerem o seu acúmulo no interior da bacia em 39.9 t ano^-1. O tipo de solo, fonte de metal para os rios, e o ciclo hidrológico com períodos de cheia e seca atuam sobre a química redox das águas. A conjunção sazonal de fatores como a natureza da matéria orgânica, pH ácido e radiação solar permitem que as águas pretas oscilem de redutora a oxidante, onde, por sua vez, ocorre o consumo de Hg⁰e degradação do metilmercúrio. Deste modo, o fluxo do mercúrio pode ser invasivo ou evasivo. Embora a metilação seja mais favorecida em águas pretas, a fotodegradação do metilmercúrio se contrapõe ao seu acúmulo, contribuindo para regular o estoque deste composto na coluna água.

Introduction

Mercury contamination in the Amazon basin became a matter of world concern when high levels of mercury were detected in fish from the Madeira river.¹ After this episode, several research groups,^2-16 have investigated this topic in different areas in the Amazon, in order to understand the sources and fate of mercury. In the Negro river basin high mercury concentrations were found in soils (average value of 170 µg kg^-1)^3-8 and in other matrices, although the median concentration in the atmosphere was relatively low, on the order of 1.3 ng m^-3.^17-19 Different from other regions in the Amazon, this basin has little gold-mining activity and there are many indications that naturally occurring mercury leaching from soil (99.7%) is the major pathway to mercury enrichment of the aquatic environment.⁸

Mercury and its related redox species show a complex cycle in the environment.^12,16,20-23 In a broad aspect, Hg²⁺, methyl mercury (MeHg) and dissolved gaseous mercury (DGM), which is almost totally Hg⁰, are the main species found, and their capacity for interconversion is responsible for the mercury dynamics. Mercury in soil is naturally present in rocks, although other sources of mercury inputs to forest ecosystems are associated with dry and wet atmospheric deposition.²⁴ Forest canopies are effective in trapping atmospheric mercury due to a high adsorption surface area for interception.^24-26 Because transfer of Hg from soil to leaves through roots is usually negligible, mercury present in vegetation can be considered as a result of atmospheric deposition.^27,28 Although some mercury compounds that accumulate on foliage are washed off by precipitation, thus increasing its concentration in soil, many studies suggest that litterfall deposition and subsequent decomposition can be considered the main sources of Hg in soil.^24,29-31 This mechanism of mercury transfer has been poorly studied in the Amazon forest.

Mercury shows a complex biogeochemical cycle in water bodies, with rates of volatilization controlled by both biotic and abiotic factors. The Hg⁰ concentration, the main chemical species of the DGM fraction, will determine the evasion/invasion of the metal in the water column. When Hg²⁺is present in the water column methylation can occur, leading to possible bioaccumulation and biomagnification. In the Negro River region, as a result of this process, fish and the riparian population show high mercury levels when compared to populations living close to white water rivers.^8,9,16

A broad project on the mercury cycle in the Negro river basin has been undertaken by our laboratories over a period of ten years in order to evaluate mercury concentrations in different compartments (air, water, soil, sediments, fish and humans) and from different mercury sources, trying to assess the soil function in the mercury cycle and to understand the factors that govern invasive and evasive fluxes in the air/water and air/soil interfaces. Our major contribution is to present the mercury budget in this area, based upon data collected during these last ten years, together with some new experiments, and to discuss factors affecting the mercury cycle in the Negro River basin, with emphasis on the organic matter, solar radiation, hydrogen peroxide formation, seasonality and soil function.

Experimental

Study area

The Negro River basin spreads over an area of 690,000 km², which represents 14% of the total area of the Brazilian Amazon, where the Negro river flows for approximately 1700 km (Figure 1).³² According to Sioli,^33,34 Amazon tributaries are classified as black water, white water and intermediate water rivers. Black water rivers such as the Negro river drain highly weathered sandy soils of the central Amazon basin, show low sediment and nutrient concentrations, blackish-colored waters rich in dissolved humic substances and acidic pH. White water bodies such as the Branco, Solimões and the Madeira river originate in the Andes and are characterized by a high suspended sediment load, neutral to slightly acidic pH, low organic matter concentration (below 9 mg C L^-1) and are rich in dissolved nutrients due to rapid weathering in piedmont regions. Intermediate water bodies present characteristics between black and white waters.

The Negro River basin is characterized by two distinct hydrological seasons: the dry period (September to February) and the wet period (rainy season from March to August), where the water level difference can reach up to 15 m. In the rainy season, rivers tend to flood, covering the forest and surrounding areas, forming the so-called 'igapós', which act as an important source of labile organic carbon to the water bodies, thus markedly affecting both the major nutrient cycles and the mercury chemistry.^3,8

Sampling periods and stations

From 1994 to 2004, several samples of different matrices were colleted and characterized along the Negro River basin and its tributaries (Figure 1) in dry (January) and wet (July) periods. Mercury concentrations, including its major species, and matrix characteristics along the basin can be found elsewhere for soil,⁸ black and white waters,^8,35 sediment,⁸ atmosphere,^8,18,35 rain water,^8,35 and fish.³⁶

Mercury inputs in the Negro river basin

Wet deposition over the Negro river basin has been estimated by combining analytical data obtained from total Hg measurements in rain water with hydrographic and pluviometric maps using Remote Sensoring (RS) and GIS (Geographic Information System) tools. The same tools were used to estimate total flux at the water/atmosphere interface.³⁵

Mercury inputs via litterfall were calculated from total mercury concentration in litterfall samples and from litterfall deposition measured in a forest plot (Figure 1). Four 1 m² litterfall nylon traps were installed in a ca. 1 ha plot at 20 cm above ground level. The litterfall (leaves only) was sampled monthly from January to December 2003. Samples were oven-dried at 60 ºC for a 24 h period and weighed.

Cleaning and sampling procedures

All precautions were taken in order to avoid contamination during sampling. The labware were placed in a HCl:water (1:4 v/v) bath for 48 h at 80 ºC on a hot plate.³⁷For water collection, bottles of polyethylene terephthalate (PET) commercialized for mineral water were used according to the recommendations of Fadini and Jardim.³⁸ The bottles were washed several times at the sampling site and filled 30 cm below the surface. For both total and reactive mercury analysis, water samples were collected and preserved for transportation to the laboratory. Water samples for organic mercury analysis were extracted using methylene choride and stored in a refrigerator for transportation.³⁷

Analytical procedures

Total and reactive mercury in surface water,⁸ bulk precipitation,^8,35 and the atmosphere,^8,35 were quantified using double-stage gold amalgamation followed by cold vapor atomic fluorescence spectrometry (CVAFS from Brooks Rand^® model 2). Organic mercury was determined after solvent extraction following a published procedure.¹⁶ DGM was determined³⁵ by purging surface water using argon and the analytical curve was constructed by injections of known concentrations of Hg saturated air.³⁹ The air/water fluxes were estimated using Fick's law and Henry's constant.³⁵ Total Hg in leaves was determined after wet digestion of ground samples at 75 ºC with a mixture of concentrated HNO₃ and 30% v/v H₂O₂, by cold vapor atomic absorption spectrometry (CVAAS, Buck Scientific-Mercury Analyser Vapor 400-A). Analytical accuracy was checked using standard reference materials^® (SRM) from the National Institute of Standard and Technology (NIST): SRM-1515 Apple leaves; error was less than 11% and triplicate analyses showed an analytical precision < 10%.

Microcosm experiments to evaluate the effects of hydrogen peroxide, organic matter and solar radiation on organic mercury dynamic

Water samples were collected in PET bottles without headspace and spiked with methyl mercury to a final concentration of 55 ng L^-1, a concentration not far from natural conditions yet measurable with confidence in the field. The bottles were maintained submerged near the top of the surface water (30 cm below the surface) so that they could receive solar radiation and be maintained at the same temperature as the river. Three water samples from each group were wrapped with aluminum foil to act as dark controls. After 0, 2, 4 and 6 h of solar radiation, samples were collected and analyzed for organic mercury, gaseous dissolved mercury and hydrogen peroxide. The experiments were performed from 11 am to 5 pm and the solar radiation intensity was monitored at 365 nm. A control group containing ultrapure water (MilliQ) spiked with methyl mercury at the same concentration was kept in the same conditions. A parallel experiment was set using catalase (1000 nmol L^-1) to keep the hydrogen peroxide concentration below 20 nmol L^-1.

Results and Discussion

Soil and soil cover roles in the mercury cycle

In this watershed, soil acts not only as a sink of atmospheric Hg depositions and a long-term source of mercury, but also plays an important role in the redox water chemistry of the Negro river.⁸ Mercury wet deposition reached values between 17 and 27 µg m^-2 y^-1, averaging 22.9 µg m^-2 y^-1, which corresponds to an input of 15.8 t y^-1 over the whole basin.³⁵ Litterfall deposition ranged from 41 g m^-2 month^-1 (April) to 133 g m^-2 month^-1 (November), resulting in 8.4 t ha^-1 yr^-1. Hg concentration in litter varied from 35.4 to 61.5 ng g^-1 (mean ± standard deviation: 48 ± 10 ng g^-1). By combining litterfall deposition and Hg concentration, mercury deposition through litterfall varied from 2.4 to 5.2 µg m^-2 month^-1, resulting in an estimated transfer of 43 ± 15 µg m^-2 y^-1. Although data were limited to one area in the basin, it is important to note that litterfall deposition was of the same order as those reported in many other studies in the Amazonian region.^30,40,41 The Hg concentrations in the litter were also on the same order than those reported by Mélières et al.³⁰ (64 ng g^-1) and Roulet et al.⁴² (99 ng g^-1) for different places in the Amazonian region, and estimated Hg litterfall deposition was in accordance with the one published by Mélières et al.³⁰ (48 ± 12 µg m^-2y^-1) for remote areas in the French Guianan forest.

Considering only the non-floodable forest area of the Negro river basin (89% of the whole basin), Hg input through litterfall would be 26.7 t yr^-1. It is important to note that in the forested areas, throughfall (the rainfall that passes through the canopy and becomes enriched in Hg because of the wash-off of dry deposited Hg compounds from the leaf surfaces) can also significantly contribute to Hg deposition to forest soils.^13,26Since the mercury concentrations in throughfall were not measured in the Negro river basin, the sum of wet deposition and litterfall deposition should therefore be a low estimate of the total atmospheric deposition in forest areas.

Magarelli and Fostier^18,19 also showed the strong influence of deforestation on gaseous mercury fluxes at the air/soil interface. In forested areas, a low emission value (1.3 ± 1.3 pmol m^-2h^-1) was observed during the day and an equivalent deposition value was observed at night, showing that soils do not act as an atmospheric Hg source in forested areas. Nevertheless, in deforested areas, fluxes were always positive (13.7 ± 10.3 pmol m^-2h^-1) clearly indicating that Hg is being emitted to the atmosphere both during the day and at night. Among the factors that control Hg emission, the soil temperature appeared as one of the strongest influences, mainly in deforested areas where higher solar exposition of the soil results in higher soil temperatures in both periods.¹⁸ A high soil temperature contributes to increasing vapor pressure for the different mercury compounds, especially those species that are highly volatile, such Hg⁰ and (CH₃)₂Hg.⁴³ The chemical and physical processes that probably control Hg emission from soil also play an important role in the distribution of different Hg species among different soil phases, which is largely associated with sorption and desorption of Hg⁰ and Hg²⁺ and redox reactions in soils induced by sunlight ⁴³ and mediated by humic substances.^44,45

As mentioned, atmospheric mercury input to soil covered by forest can be expected to be significantly higher than in deforested areas, while Hg emissions are significantly enhanced in deforested areas. Soil coverage is also a determinant parameter in controlling Hg transfer from soil to aquatic systems because both leaching and soil erosion increase in deforested areas. Working in another Amazonian region, Fostier et al.⁷ showed that Hg fluxes between terrestrial and aquatic systems were three times higher in deforested areas when compared to the pristine forest area of the same basin. In addition, deforested areas contribute to water body siltation, increasing the mercury stock, since experiments on mercury leaching showed an average leaching capacity of 1.5 mg of mercury per kg of soil in 14 days of contact with pure water, under laboratory conditions.⁸

In the Negro river basin, studies performed with soil samples from floodable and non-floodable areas show the importance of the soil organic matter in the Hg cycle.^45,46It has been shown that soil organic matter acts as a mercury sink, and that in this type of soil, Hg(II) sorption is chiefly governed by the organic matter content.³⁰ Consequently, in deforested areas where organic matter contents are lower due to intensive leaching, higher amounts of mercury will be desorbed from soils and transferred to the aquatic system. The correlation (r² = 0.68) between total mercury concentration (Hg_total) and dissolved organic carbon (DOC) from various rivers of the Negro River basin also corroborates the importance of organic matter in mercury transport from drainage areas to the aquatic system.⁴⁷

Dissolved gaseous mercury (DGM) formation/consumption

Due to seasonal flooding, which can reach up to 11% of the total forest area, there is an important input of fresh (labile) organic matter to the water bodies. In a recent work, Bisinoti⁴⁸ has pointed out the importance of the hydrological cycle for organic matter turnover in the Negro River basin, which, associated with high solar intensity and low pH, can significantly alter the redox conditions in the water column, especially in the sunlit portion. Both reductive and oxidant conditions vary as a function of organic matter aging in black waters.

In white water bodies, with nearly neutral pH, it has been suggested that photogenerated H₂O₂ is able to reduce Hg²⁺ to Hg⁰ (H₂O₂ + 2OH + Hg²⁺ = O₂ + 2H₂O + Hg⁰). In turn, in black waters, the existence of an oxidative mechanism converting Hg⁰ to Hg²⁺ by photogenerated H₂O₂ is assumed (H₂O₂ + 2H⁺ + Hg⁰ = 2H₂O + Hg²⁺)⁴⁹as also discussed by other autors.^50-52 Both redox reactions would involve H₂O₂ photogenerated by UV light and dissolved organic matter interactions.^53-55Amon and Benner,⁵⁶ working with water samples from the Negro River, verified that 15% of the dissolved organic carbon stock was composed of photoreactive labile species degradable to CO₂ when exposed to sunlight for periods up to 27 h. Recently, Silva et al.⁴⁹ have reemphasized major aspects related to this complex redox water chemistry.

Other natural parameters that are affected by the redox chemistry in the Negro River basin include the Fe²⁺/Fe³redox couple through Fenton-type reactions (H₂O₂+ Fe²⁺ = ^·OH + OH^- + Fe³⁺), where ^·OH radicals are able to oxidize Hg⁰ to Hg²⁺.⁵⁷ Recently, Silva et al.⁴⁹ have discussed this possible oxidative mechanism in the black water of the Negro River basin. Lalonde at al.⁵⁸ have shown the role of semiquinones and chloride in the photooxidation of Hg⁰ in laboratory experiments. From the studies carried out in the evaluation of mercury flux at the water/air interface, the predominant mechanism observed for black waters is an invasive flux during the day and an evasive flux at night.^35,49

It is interesting to note that, for white water bodies, the observed trend is the opposite, with invasive flux during the night and evasive flux under sun light with respect to the water phase. This is explained by the presence of photogenerated hydrogen peroxide that favors the reduction of mercury at pH values near neutrality.

This behavior, although attributed principally to hydrogen peroxide, is not always true. During the periods when fresh and labile organic matter is washed from soils to the water bodies, e.g. the beginning of the flooding season, this load of reactive material will consume hydrogen peroxide, thus reducing Hg²⁺to Hg⁰, even under acidic and sunlit conditions, as shown in Figure 2. These mercury fluxes were estimated over 28 hours, between 9 am the first day and 1 pm on the second day. On both days, atypical high DGM fluxes of 3.19; 3.80 and 1.88 pmol m^-2h^-1 were observed during the sunlight period, at 9:00; 16:00 and 13:00 (second day) respectively.

Methylation/Demethylation

Water bodies in the Negro River basin offer propitious conditions for the methylation process, especially at the beginning of the rainy season, due to anaerobic conditions, the presence of labile organic matter and the presence of Hg²⁺, as shown by Bisinoti and Jardim.^16,59 However, due to intense solar radiation, a suitable oxidizing condition is observed, as discussed earlier, that initiates the photodestruction of the methyl mercury (MeHg) formed to Hg²⁺. Sellers et al.⁶⁰ showed that MeHg could be photodegraded in surface waters via abiotic processes. Solar radiation can be responsible for MeHg transformation to Hg²⁺ and Hg⁰. Similar findings were observed by Siciliano et al.⁶¹and Lalonde et al.⁵⁸

Manipulated experiments using black water samples spiked with MeHg and exposed to solar light are shown in Figure 3. As observed, MeHg is not destroyed in the dark, and H₂O₂ seems to play an important role in the destruction of the organic mercurial species as the presence of catalase decreased by half the amount of MeHg destroyed in 6 h of solar exposure. The principal product of MeHg destruction is Hg⁰(DGM). Similar experiments using different types of Amazonian waters showed the following rates of methyl Hg destruction: black waters (5 ng L^-1 h^-1) > white waters (2.8 ng L^-1 h^-1) > ultrapure water (2.5 ng L^-1 h^-1). The half-lives (t_1/2) for methylmercury photodegradation followed first order kinetics with t_1/2of 7 and 4 h for white and black waters, respectively.^48,62

In the Negro River basin, MeHg concentration is lower in white waters (< 0.01 to 0.41 ng L^-1) compared to black waters (< 0.01 to 1.63 ng L^-1). However, despite the fact that black water bodies present more favorable conditions for methylation, the amount of organic mercurial species is lower than expected, as it is controlled by high rates of photodestruction.

Mercury mass balance in the Negro River basin

Computing the major sources and sinks of mercury in the Negro River basin over the last 12 years of extensive studies, Figure 4 shows a broad picture of the mercury mass balance in the watershed. Total metal input (42.5 t y^-1) is mainly constituted from wet deposition (15.8 t y^-1) and litterfall deposition (26.7 t y^-1). Nevertheless it should be emphasized that this value could be underestimated because throughfall deposition has not been estimated, whereas litterfall deposition was calculated only for the non-floodable forest areas. Total output accounts for 2.61 t y^-1, i.e., the sum of fluvial transport (2.2 t y^-1),⁸ evasive flux at the water/atmosphere interface (0.26 t y^-1)³⁵ and deforested area (0.15 t y^-1).¹⁸ Fluvial transport represents mercury flux from the drainage basin, including all chemical and physical species from flooded or non-flooded areas. In the forested areas, equal diurnal emission and nocturnal deposition rates at the soil/air interface result in no net Hg emission to the atmosphere. Assuming these average fluxes, the accumulation rate into the Negro River basin is 39.9 t yr^-1.

Conclusions

A long-term study of mercury in one of the most pristine watersheds in the Amazon has shown that, in this naturally enriched metal area, mercury output transport mechanisms are less than the mercury inputs, which leads to an accumulative process into the basin. Although the model adopted is this work is simplified, it clearly shows that the soil in the Negro River basin acts as a sink of mercury, and long-term source of mercury to the water bodies. Mercury concentration in the water column was positively correlated with dissolved organic carbon (DOC), indicating metal-organic-bound species, especially involving humic and fulvic substances, which are the main form transported from watershed to aquatic systems through runoff.⁶³

In reaching white and black waters, mercury from terrestrial sources finds different redox conditions that vary according to the hydrological cycle and soil type in the drainage area. Black waters, with acid pH and high DOC level, and facing a dry period with no input of fresh labile organic matter from soil, creates a natural sunlit oxidative barrier that avoids DGM formation (thus mercury export), and degrades part of the methylmercury formed. On the other hand, although propitiating better conditions for methylation, which ultimately would be translated into bioaccumulation and biomagnification, a seasonal destructive redox barrier is responsible for regulating the methylmercury concentration in this system.

Finally, it has been shown that the mercury cycle in the Negro River basin is clearly associated not only to the hydrological regime, but also regulated by sun light, the availability of organic matter, the pH and many other secondary substances and by-products (such as H₂O₂), demanding a great deal of integrated research in order to elucidate the fate and the associated risks of mercury in the area.

Acknowledgments

The authors would like to thank Prof. C. H. Collins for revising the manuscript. This work was supported by FAPESP (02/03395-1; 00/13517-1).

Received: February 11, 2009

Web Release Date: June 26, 2009

FAPESP helped in meeting the publication costs of this article.

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36. Dorea, J. G.; Barbosa, A. C; Silva, G. S.; Comp. Biochem. Physiol., Part C: Toxicol. Pharmacol. 2006, 142, 275.
37. Bisinoti, M. C.; Júnior, J. L. B.; Malm, O.; Guimarães, J. R.; Jardim, W. F.; Quim. Nova 2006, 29, 1169.
38. Fadini, P. S.; Jardim, W. F.; Analyst 2000, 125, 549.
39. Dumarey, R.; Temmerman, E.; Dams, R.; Hoste, J.; Anal. Chim. Acta 1985, 170, 337.
40. Smith, K.; Gholz, H. L.; Oliveira, F. D.; Forest Ecol. Manag. 1998, 109, 209.
41. Rodrigues, W. A.; Furch, K.; Klinge, H.; Amazoniana- Limnologia et Oecologia Regionalis Systemae Fluminis Amazonas 2001, 16, 441.
42. Roulet, M.; Lucotte, M.; Water, Air, Soil Pollut. 1995, 80, 1079.
43. Schluter, K.; Environ. Geology 2000, 39, 249.
44. Oliveira de, L. C.; Serudo, R. L.; Botero, W. G.; Mendonça, A. G. R.; Dos Santos, A.; Rocha, J. C.; Quim. Nova 2007, 30, 274.
45. Serudo, R. L.; Oliveira de, L. C.; Rocha, J. C.; Paterlini, W. C.; Rosa, A. H.; Silva da, H. C.; Botero, W. G.; Geoderma 2007, 138, 229.
46. Miretzky, P.; Bisinoti, M. C.; Jardim, W .F.; Chemosphere 2005, 60, 1583.
47. Silva, G. S.; PhD Thesis, Universidade Estadual de Campinas, Brazil, 2004.
48. Bisinoti, M. C.; Ph.D. Thesis, Universidade Estadual de Campinas, Brazil, 2005.
49. Silva, G. S.; Jardim, W. F.; Fadini, P. S.; J. Braz. Chem. Soc. 2009, in the press.
50. Brosset, C.; Water, Air, Soil Pollut. 1987, 34, 145.
51. Schroeder, W.; Lindqvist, O.; Munthe, J; Xiao, Z.; Sci. Total Environ. 1992, 125, 2366.
52. Amyot, M.; Mierle, G.; Lean, D. R. S.; Mcqueen, D. J.; Environ. Sci. Technol. 1994, 28, 2366.
53. Zika, R. G.; Moffett, J. W.; Petasne, R. G.; Cooper, W. J.; Saltzman, E. S.; Geochim. Cosmochim. Acta. 1985, 49, 1173.
54. Cooper, W. J.; Lean, D. R. S.; Environ. Sci. Technol 1988, 22, 1156.
55. Cooper, W.; Lean, D. R. S.; Environ. Sci. Technol. 1989, 23, 1425.
56. Amon, R. M. W.; Benner, R.; Geochim. Cosmochim. Acta 1996, 60, 1783.
57. Southworth, B. A.; Voelker, B. M.; Environ. Sci. Technol 2003, 37, 1130.
58. Lalonde, J. D.; Amyot, A.; Orvoine, J.; Morel, F. M. M.; Auclair, J-C.; Ariya, P. A.; Environ. Sci. Technol. 2004, 38, 508.
59. Bisinoti, M. C.; Sargentini Junior, E.; Jardim, W. F.; J. Braz. Chem. Soc. 2007, 18, 544.
60. Sellers. P.; Kelly, C. A.; Rudd, J. W. M.; Machutchin, A. R.; Nature 1996, 380, 694.
61. Siciliano, S. D.; Lean, D. R.; Environ. Toxicol. Chem 2002, 21, 1184.
62. Bisinoti, M. C.; Jardim, W. F.; RMZ-M&G 2004, 51, 825.
63. Oliveira, L. C.; Sargentini Jr., E.; Rosa, A. H.; Rocha, J. C.; Simões, M. L.; Martin Neto, L.; Silva, W. T. L.; Serudo, R. L.; J. Braz. Chem. Soc. 2007, 18, 860.

*

e-mail:

wfjardim@iqm.unicamp.br

Publication Dates

Publication in this collection
04 Aug 2009
Date of issue
2009

History

Accepted
26 June 2009
Received
11 Feb 2009

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

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[35] 35. Silva, G. S.; Jardim, W. F; Fadini, P. S.; Sci. Total Environ 2006, 368, 189.

[36] 36. Dorea, J. G.; Barbosa, A. C; Silva, G. S.; Comp. Biochem. Physiol., Part C: Toxicol. Pharmacol. 2006, 142, 275.

[37] 37. Bisinoti, M. C.; Júnior, J. L. B.; Malm, O.; Guimarães, J. R.; Jardim, W. F.; Quim. Nova 2006, 29, 1169.

[38] 38. Fadini, P. S.; Jardim, W. F.; Analyst 2000, 125, 549.

[39] 39. Dumarey, R.; Temmerman, E.; Dams, R.; Hoste, J.; Anal. Chim. Acta 1985, 170, 337.

[40] 40. Smith, K.; Gholz, H. L.; Oliveira, F. D.; Forest Ecol. Manag. 1998, 109, 209.

[41] 41. Rodrigues, W. A.; Furch, K.; Klinge, H.; Amazoniana- Limnologia et Oecologia Regionalis Systemae Fluminis Amazonas 2001, 16, 441.

[42] 42. Roulet, M.; Lucotte, M.; Water, Air, Soil Pollut. 1995, 80, 1079.

[43] 43. Schluter, K.; Environ. Geology 2000, 39, 249.

[44] 44. Oliveira de, L. C.; Serudo, R. L.; Botero, W. G.; Mendonça, A. G. R.; Dos Santos, A.; Rocha, J. C.; Quim. Nova 2007, 30, 274.

[45] 45. Serudo, R. L.; Oliveira de, L. C.; Rocha, J. C.; Paterlini, W. C.; Rosa, A. H.; Silva da, H. C.; Botero, W. G.; Geoderma 2007, 138, 229.

[46] 46. Miretzky, P.; Bisinoti, M. C.; Jardim, W .F.; Chemosphere 2005, 60, 1583.

[47] 47. Silva, G. S.; PhD Thesis, Universidade Estadual de Campinas, Brazil, 2004.

[48] 48. Bisinoti, M. C.; Ph.D. Thesis, Universidade Estadual de Campinas, Brazil, 2005.

[49] 49. Silva, G. S.; Jardim, W. F.; Fadini, P. S.; J. Braz. Chem. Soc. 2009, in the press.

[50] 50. Brosset, C.; Water, Air, Soil Pollut. 1987, 34, 145.

[51] 51. Schroeder, W.; Lindqvist, O.; Munthe, J; Xiao, Z.; Sci. Total Environ. 1992, 125, 2366.

[52] 52. Amyot, M.; Mierle, G.; Lean, D. R. S.; Mcqueen, D. J.; Environ. Sci. Technol. 1994, 28, 2366.

[53] 53. Zika, R. G.; Moffett, J. W.; Petasne, R. G.; Cooper, W. J.; Saltzman, E. S.; Geochim. Cosmochim. Acta. 1985, 49, 1173.

[54] 54. Cooper, W. J.; Lean, D. R. S.; Environ. Sci. Technol 1988, 22, 1156.

[55] 55. Cooper, W.; Lean, D. R. S.; Environ. Sci. Technol. 1989, 23, 1425.

[56] 56. Amon, R. M. W.; Benner, R.; Geochim. Cosmochim. Acta 1996, 60, 1783.

[57] 57. Southworth, B. A.; Voelker, B. M.; Environ. Sci. Technol 2003, 37, 1130.

[58] 58. Lalonde, J. D.; Amyot, A.; Orvoine, J.; Morel, F. M. M.; Auclair, J-C.; Ariya, P. A.; Environ. Sci. Technol. 2004, 38, 508.

[59] 59. Bisinoti, M. C.; Sargentini Junior, E.; Jardim, W. F.; J. Braz. Chem. Soc. 2007, 18, 544.

[60] 60. Sellers. P.; Kelly, C. A.; Rudd, J. W. M.; Machutchin, A. R.; Nature 1996, 380, 694.

[61] 61. Siciliano, S. D.; Lean, D. R.; Environ. Toxicol. Chem 2002, 21, 1184.

[62] 62. Bisinoti, M. C.; Jardim, W. F.; RMZ-M&G 2004, 51, 825.

[63] 63. Oliveira, L. C.; Sargentini Jr., E.; Rosa, A. H.; Rocha, J. C.; Simões, M. L.; Martin Neto, L.; Silva, W. T. L.; Serudo, R. L.; J. Braz. Chem. Soc. 2007, 18, 860.