Geochronology and heavy metal flux to Guanabara bay, Rio de Janeiro state: a preliminary study

Baptista Neto, José A.; Peixoto, Tomás C.S.; Smith, Bernard J.; Mcalister, John J.; Patchineelam, Soraya M.; Patchineelam, Sambasiva R.; Fonseca, Estefan M.

doi:10.1590/0001-3765201394612

Abstracts

Guanabara Bay, located in Rio de Janeiro state. It is surrounded by the second most important metropolitan area of the country. Over recent decades, land disturbance and urbanization in the surrounding area has significantly increased sediment input to the bay and had a negative effect on its overall environmental. This is especially related to high volumes of untreated sewage and industrial effluents. This study evaluates the history of this human impact through detailed examination of a sediment core taken from the northern portion of Guanabara Bay. A geochronology is established using ²¹⁰Pb dating and related to organic carbon and heavy metal fluxes to the sediments. This gave a calculated net average sedimentation rate for the core of 0.67 cm.year^-1. The organic carbon and heavy metals flux started to increase at the beginning of the last century and the highest values was observed in the top of the cores.

²¹⁰Pb; geochronology; Flux of heavy metal; Guanabara Bay

A Baía de Guanabara, localizada no estado do Rio de Janeiro, é cercada pela segunda mais importante área metropolitana do país. Nas últimas décadas, a urbanização e outros processos na área circundante têm aumentado significativamente a entrada de sedimentos para a baía, tendo um efeito negativo sobre todo o meio ambiente. Estes impactos negativos estão relacionados com grandes volumes de esgoto sem tratamento e efluentes industriais. O presente estudo avalia a história deste impacto humano através do exame detalhado de um testemunho coletado na porção norte da Baía de Guanabara. A geocronologia é estabelecida usando ²¹⁰Pb e relacionada com o carbono orgânico e fluxos de metais pesados para os sedimentos. Os resultados indicaram uma taxa de sedimentação média de 0,67 cm.y^-1. O fluxo de carbono orgânico e metais pesados começaram a aumentar no início do século passado e os maiores valores foram observados no topo do testemunho.

²¹⁰Pb; geocronologia; Fluxo de metais pesados; Baía de Guanabara

INTRODUCTION

Estuarine and coastal lagoon sediments provide unique records of the environmental history of a drainage basin, and frequently yield detailed evidence of the changes to catchment dynamics caused by human activities (Arnason and Fletcher 2003, Di Lauro et al. 2004, Sanders et al. 2006). The impacts of anthropogenic changes have greatly accelerated over the last 150 years and have been particularly associated with important transformations in the aquatic environments linked to increased pollution loading resulting from rapid urbanization and the growth of industrial activities (Ip et al. 2004, Feng et al. 2004). Amongst the most prominent of these pollutants are heavy and trace metals (hereafter grouped as heavy metals) that show a particular affinity for the fine sediments that characterize many nearshore environments and a propensity for long-term persistence within the sediment record (Li et al. 2001, Arnason and Fletcher 2003). As a byproduct of this persistence, vertical concentration profiles of heavy metals in estuarine sediment cores have been used increasingly over the last 30 years as a means of understanding environmental change within contributing catchments (Vaalgamaa 2004). This strategy has been greatly aided by the advent of radiometric dating methods, particularly ²¹⁰Pb (Marques Jr et al. 2006) that have allowed the construction of geochronologies linked to the sedimentation (e.g. Robbins and Edgington 1975, Oldfield and Appleby 1984, Sharma et al. 1987, Simões Filho 1993, Turner and Delorme 1996, Godoy et al. 1998, Patchineelam et al. 1999, Di Lauro et al. 2004, Sanders et al. 2006). Since the introduction of ²¹⁰Pb dating for sediments by Goldberg (1963) it has been widely applied to lakes, estuaries and coastal marine environments as a geochronological tool (Appleby and Oldfield 1992, Matsumoto 1975, 1987, Robbins and Edgington 1975, Robbins and Herche 1993, Smith 2001, Lu and Matsumoto 2005). The natural radionuclide of ²¹⁰Pb (T1/2 = 22.26 yr) is a byproduct of ²²⁶Ra decay (Ruiz-Fernández and Hillaire-Marcel 2009) and is supplied to the aquatic environment by atmospheric deposition, although it can also result from the decay of dissolved ²²⁶Ra in the open ocean (where production of ²¹⁰Pb from ²²⁶Ra can exceed the atmospheric ²¹⁰Pb contribution by factors of 2-20; Cochran 1992). Because of its relatively short half-life, ²¹⁰Pb has been shown to be an ideal tracer for dating aquatic sediments deposited during the last 100 years, a period of time during which appreciable environmental changes have occurred due to urbanization and industrialization. However, there has been very little research into recent metal fluxes to the bay. In order to address this gap in knowledge and to estimate the magnitude of heavy metal fluxes to the sediments of Guanabara Bay, the present study aims to assess the fluxes of key metals (Zn, Pb, Cu, Cr and Ni) into Guanabara Bay through an examination of their concentration in a dated sediment core using chemical and ²¹⁰Pb analyses. The results will be used to evaluate the anthropogenic inputs of metals into the sediments of Guanabara Bay over time, particularly the past 50 years of rapid economic development.

Besides the huge environmental pollution in Guanabara Bay, the studied area is one of the main protected area in this bay, with the lower heavy metal concentrations (Baptista Neto et al. 2006). However, the catchment of the rivers that flows to this region will receive a huge petrochemical complex, already under construction, which will increase the amount of heavy metal and sediments to the studied area, making this baseline data extremely important, concerning the future of this area.

In the last 100 years the catchment area around Guanabara Bay has been strongly modified by human activities, in particular deforestation and uncontrolled settlement, which have generally increased river discharges and sediment loads flowing into the bay. Consequently the average rates of sedimentation are thought to have increased to 1-2 cm.year^-1 (Godoy et al. 1998), although this figure has yet to be substantiated.

STUDY AREA

Guanabara Bay (Figure 1) lies entirely within Rio de Janeiro State, Southeast Brazil between 22°40' - 23° 00'S and 43° 00' - 43° 18'W. It is one of the largest bays on the Brazilian coastline and covers an area of approximately 384 km², including a number of islands. According to Amador (1997) the coastline of the bay is 131 km long; the mean water volume is 1.871,09 m³, measures 28 km from west to east and 30 km from south to north and is constrained by a narrow entrance that is only 1.6 km wide (Kjerfve et al. 1997). The bay has a complex bathymetry with a marked central channel that is some 400 m wide, stretches more than 5 km into the bay from the mouth, and is defined by the 30 m isobath. The deepest point of the bay measures 58 m and is located within this channel (Kjerfve et al. 1997). According to the same authors, north of the Rio de Janeiro-Niterói bridge, the channel loses its characteristics as the bay rapidly becomes shallower, with an average depth of 5.7 m, due in the main to high rates of sedimentation that have accelerated over the last century in response to human activity in the catchment area. The climate is humid sub-tropical with a mean annual temperature between 20°C to 25°C and an annual rainfall of 2,500 mm at higher altitudes and 1,500 mm at lower altitudes between December and April. (Nimer 1989).

Figure 1
Map of the location of the studied area.

Figure 1 - Map of the location of the studied area.

Guanabara Bay is one of the most prominent coastal bays in Brazil. The bay is in reality an estuary of 91 rivers and channels, surrounded by the cities of Rio de Janeiro, Duque de Caxias, São Gonçalo, Niterói and many other small cities and villages. The rapid urbanization and industrialization in the Guanabara Bay region since the 1950s has resulted in growing pressure on the local environment (Amador 1997). This has lead to increased contamination of the bay from the combined inputs of the numerous rivers containing untreated sewage effluent, industrial discharges, urban and agricultural runoff, atmospheric fallout, all of which has had a significant impact on the aquatic environment (Rebello et al. 1986, Baptista Neto et al. 2006, Carreira et al. 2002, McAlister et al. 2000, 2005). The bay also hosts two airports, holds one of the country's main naval bases and is crossed by a 12 km long bridge used by thousands of cars daily. Previous studies of heavy metal pollution in Guanabara Bay have pointed out that the bay is one of the most polluted ecosystems in Brazil (Rebello et al. 1986, Vandenberg and Rebello 1986, Leal and Rebello 1993, Barrocas and Wasserman 1993, Baptista Neto et al. 2000, 2006, Faria and Sanchez 2001, Machado et al. 2002, Carreira et al. 2002, Kehrig et al. 2003, Vilela et al. 2004). Included amongst these assessments are a number of studies that have examined the spatial distribution of heavy metals and organic contaminants in recent sediments of Guanabara Bay (Rebello et al. 1986, Vandenberg and Rebello 1986, Leal and Rebello 1993, Barrocas and Wasserman 1993, Baptista Neto et al. 2000, 2006).

MATERIALS AND METHODS

This study examines a sediment core 7 cm in diameter and 180 cm deep collected in the north of Guanabara Bay close to a mangrove system and a protected environmental area in approximately one-meter of water. After drying at air temperature, the core was split longitudinally and described. One half was sampled by collecting slices at 2 cm intervals down to a depth of 40 cm for ²¹⁰Pb analyses that employed gamma-ray spectrometry. The other half was sampled in a similar manner along the complete length of the core for particle size, organic carbon and elemental analyses. The sediment core was collected closer to an environmental protected area (APA) of Guapimirim, in order to avoid the most polluted and disturbed area of Guanabara Bay. This area was chose after an analyze of a seismic profile to certify that the area was not disturbed by anthropogenic activity.

Particle size analysis was carried out using a Malvern Mastersizer Microplus, MAF 5001. The water content and porosity of the core were measured based in the methodology proposed by Durham and Joshi (1980). Gamma-ray measurements were made using a semi-planar intrinsic germanium high purity coaxial detector with 40% efficiency. This was housed in a lead shield and coupled to a multichannel analyzer. Activity was calculated according to well-established methods (Patchineelam and Smoak 1999). The sedimentation rate was calculated by dividing the ²¹⁰Pb decay constant by the slope of the log-linear plot of unsupported ²¹⁰Pb versus depth (Appleby and Oldfield 1992). Total organic carbon was determined using a CS infrared analyser model Eltra Metalyt 1000CS. Sub-samples for chemical analysis were oven dried between 30-35°C since extractable metals were examined and passed through a 2 mm diameter nylon mesh sieve (Hesse 1971). The < 63 µm fraction was collected by further sieving a representative portion of the < 2 mm fraction through a nylon mesh. This size fraction was analysed as it is relatively undiluted by coarser sizes and allows a more accurate prediction of the threat to an ecosystem by heavy metals (Forstner and Whittmann 1983). Samples were digested in aqua regia under pressure using a Perkin Elmer microwave digestion system (USEPA 3051a). Sample blanks and a reference sediment WQB-1 from the National Laboratory for Environmental Testing, Burlington, Canada, was also analysed at regular intervals to monitor quality control. Sample extracts were filtered through Whatman No. 40 filter papers into acid washed high-density polyethylene (HDPE) containers and diluted to a volume of 25 mL in deionised water. Analytical standards were prepared by diluting a 1,000 mg.L^-1 BDH stock solution that is traceable to the NIST Certified Reference Institute. Elemental analysis (Pb, Zn, Ni, Cr, Cu, Mn, Fe) was carried out using a Perkin Elmer Analyst 200 atomic absorption spectrophotometer.

Sedimentation, compaction and the rate of accumulation of elements within the sediment per unit of area are constant and the rate of time is given by the formula

T = ϖ ×ρ _s (1 − ϕ)×C×10⁴

where: T is the burial rate (mg.m^-2.year^-1); ω is the sedimentation rates (cm.year^-1); ρs is the mean density of solids (g.cm^-3); Ø is the porosity; C is the concentration of the element in the sediment (mg.g^-1); and 104 is the factor for conversion of cm^-2 to m^-2. (Berner 1980).

RESULTS AND DISCUSSION

Pollution is a negative outcome of rapid develop-ment and industrialization. Marine bays adjacent to metropolitan areas are strongly polluted by domestic, industrial and other sources of waste and anthropogenic impacts have seriously influenced the whole marine ecosystem. Heavy metals are produced from a variety of natural and anthropogenic sources, for example, metal pollution can result from direct atmospheric deposition, geologic wea-thering or through the discharge of agricultural, municipal, residential or industrial waste products (Demirak et al. 2006).

Heavy metal analysis in estuarine sediment cores has become popular in the study of environmental change over the past 40 years (Audry et al. 2004, Cochran et al. 1998). According to Farmer et al. (1996) and Ip et al. (2004) the increase in metal concentrations within sediment cores is considered as being due to temporal variations in atmospheric deposition, catchment runoff, effluent inflow and dumping of waste from various human activities. In the absence of long-term monitoring data, the sedimentary record can be used to provide retrospective information on the past characteristics of a coastal environment.

Heavy metals and other pollutants are adsorbed onto fine particle surfaces of sediments since they have a very high specific surface area, therefore scavenging by suspended particulate matter and subsequent sedimentation creates a repository that provides valuable historical information on the temporal trend of input from pollutants into aquatic ecosystems (Goldberg et al. 1977). If there is a valid accumulation rate these records can provide specific data about rates of sediment accumulation and the anthropogenic flux of pollutants (Axelsson and El-Daoushy 1989). According to Sanchez-Cabeza and Druffel (2009), under certain conditions, sediments provide a reliable record of pollution levels and an indication of the state of an ecosystem. For this to be possible, however, an accurate chronology such as that provided by linked ²¹⁰Pb dating is essential.

The percentage of fine sediment increased from a depth of 80 cm to the top of the core and varied between 50% to 90% throughout (Figure 2). Since the porosity of the core was fairly constant throughout, a correction for compaction was not required. The sedimentation rate calculated for the analyzed core through the CIC model was 0.67 cm.year^-1. This value is within the same range as that calculated in the first 40 cm of a core taken from the same area of Guanabara Bay using a CRS model which measuring ²¹⁰ Bi decay (Godoy et al. 1998) (Figure 3). This calculated sedimentary rate can be considered high when compared to other less impacted environments in the Rio de Janeiro State, such as the Guarapina lagoon, where the calculated sedimentary rate was 0.27 cm.year^-1 (Peixoto et al. 2005). In Sepetiba Bay, another impacted environment close to the study area, the estimated sedimentary rate was 0.65 cm.year^-1 (Oliveira 2005). However, Guanabara Bay is now considered as one of the most polluted and impacted bays along the Brazilian Coastline.

Figure 2
Percentage of fine sediments in sediment core.

Figure 3
Profile the Ln excess activity ²¹⁰Pb and the rates of sedimentation calculated for the sediment core.

The increase in fine sediments from a depth of 80 cm to the top of the core (Figure 2), corresponds to a ²¹⁰Pb dating of 54 years ago and a sedimentation rate around 0.67 cm.year^-1. According to Pagliosa et al. (2006) an industrial expansion in Brazil in the mid-1950s promoted rapid urban growth that took place mainly around coastal areas. Urban sprawl has caused changes in the physical, chemical and biological characteristics of estuarine systems (Ridgway and Shimmield 2002). Increase in the amount of sediment entering Guanabara Bay is not only due to an increase in catchment erosion, but also to littoral modifications that is a direct result of land reclamation (Amador 1997).

Organic carbon flux was calculated by using a value of 2.5 g.cm^-3 to represent the average density of the dry solid. Results show a significant increase in organic carbon flux where a value of 76 g.C.m^-2.year^-1 at the beginning of the century reached a value of 370 g.C.m^-2.year^-1 in the most recent sediment layers (Figure 4). Compared to other studies carried out in various other environments, Guanabara Bay shows higher organic flux values (Table I).

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TABLE I
Flux of organic carbon in sediments from different environment all over the world.

Figure 4
Flux of organic carbon in the sediment core.

Carreira (2000) found a similar pattern for organic carbon flux in recent sediments from Guanabara Bay. A core collected from an area close to the present study, showed an organic carbon flux ranging from 22 g.C.m^-2.year^-1 to 272 g.C.m^-2.year^-1. These values are lower than those found in the present study, however, the same author found values of 500 g.C.m^-2.year^-1 in others areas of Guanabara Bay, confirming an increase in organic matter and eutrophication within the bay.

Several studies with respect to heavy metals and organic carbon concentrations in sediment cores collected from the Brazilian coastline have already been carried out. However, very few studies have examined the flux of heavy metals in these environments. Therefore this combination of ²¹⁰Pb dating and heavy metal analysis provides a better understanding and a useful historical record of the heavy metal fluxes within Guanabara Bay.

Table II shows all the metal concentrations throughout the core profile and figure 5 shows the heavy metal flux. Cr concentrations range from 21.25 ppm to 47.5 ppm, with an average of 39.4 ppm, the Cr flux to the sediment range from 187.1 to 318.2 g.Cr.m^-2.year^-1. Cu concentrations range from 8.7 ppm to 23.7 ppm with an average 17ppm, the Cu flux to the sediment range from 73.1 to 142.7 g.Cu.m^-2.year^-1. Zn ranges from 31.2 pm to 112.5 ppm with an average of 79.7 ppm, the Zn flux to the sediment range from 275.01 to 669.9 g.Zn.m^-2.year^-1. Pb is from 21.2 to 397.5 ppm with an average 68.8 ppm, the Pb flux to the sediment range from 183.6 to 2,629.7 g.Pb.m^-2.year^-1 and Ni ranges from 27.5 ppm to 53.7 ppm with an average of 45.7 ppm, the Ni flux to the sediment range from 227 to 318 g.Ni.m^-2.year^-1. Results show that most of the metals increase from the bottom to the top of the core, i.e. from the past to the present. Lead, Cu and Zn show fluctuating concentrations with an increasing pattern, where subsurface sediments record the highest values. A decrease in their concentrations occurs at the top of the core implying that the flux of these metals have progressively increased with time, but have reduced in concentration over recent years due to the more stringent rules that have been applied in an attempt to reduce toxic air emissions.

Significant increases in heavy metals in the upper part of the core, after the 1950's, correspond to urbanization and industrialization processes during this period. Heavy metal accumulations prior to 1950 (Figure 5) may be linked to the deforestation that occurred in the area during this period. Lead, Zn, Cr, Ni and Cu concentrations in the core profile are presented in Figure 5. The highest concentrations were observed in the upper part of the core 1997, in the modern time, which correspond the increased amount of the sewage input in the bay (Table II). The increases in Zn, Cu and Pb concentrations in the surface sediments of Guanabara Bay have been reported in previous studies (Rebello et al. 1986, Vandenberg and Rebello 1986, Leal and Rebello 1993, Baptista Neto et al. 2000, 2006, Faria and Sanches 2001, Machado et al. 2002). In the present study, however, it is interesting to note that increases in the concentrations of Pb, Cu, Cr, Ni and Zn in this core all appear before the recent period (from the 1950s). These accumulations could be attributed to increased inputs from natural erosion derived from the rapid deforestation carried out in this area during the colonial period followed by the rapid industrial development and urbanisation in the last few decades, mainly from 1959. These accumulations in Pb, Cu, Cr, Ni and Zn concentrations after the 1950s correspond to the increase in urban activities that occurred over this period of time. Point-source inputs of these elements to aquatic environments include industrial effluents, municipal wastewaters, emissions from smelting operations and fossil fuel combustion. Today much of the anthropogenic Zn is derived from fossil fuel combustion (Nriagu and Davidson 1980) and automobile tire wear (Callender and Rice 2000). Copper originates from smelters, fossil fuel uses, industrial discharges, agriculture, mining and wastewaters, and mainly by untreated sewage (Valette-Silver 1992). Pb content increased in recent layers is due probably as consequence of the gas emission from vehicles that employed gasoline containing anti-knock based in lead, during several years. The bridge over the bay favours its subsequent transfer to the bay's water, and the increased concentrations of Ni and Cr are also related with the polluted wastes dumped by the industrial and urban activities in the zone. Analysis of this sediment core from Guanabara Bay reflects a trend of increasing metal concentrations, that started in the 1950s (Baptista Neto et al. 1999).

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TABLE II
Flux of heavy metal to Guanabara Bay in different periods.

Figure 5
The profile of (a) Ni (g.Ni.m^-2.year^-1), (b) Cr (g.Cr.m^-2.year^-1), (c) Pb (g.Pb.m^-2.year^-1), (d) Cu (g.Cu.m^-2.year^-1) and (e) Zn (g.Zn.m^-2.year^-1) concentrations over time in the sediment core.

CONCLUSIONS

Results from this study highlights the importance of combining both heavy metal and Pb²¹⁰ analyses to examine the flux of heavy metals into Guanabara Bay and the environmental changes over a period of time.

A value of 0.67 cm.year^-1 for the sedimentation rate in Guanabara Bay would indicate the level of human impact in the sediment cycle within the Bay, since this rates is very high compared to other less impacted environment in SE of Brazil.

The concentration of heavy metals shows a constant increased over the last 50 years, with the highest levels in the top layer of the core. This time period is related to an increase of urbanization (post-1950) and deforestation (pre-1950) in the catchment area. The same pattern was also observed for the organic carbon flux, which could indicate the recent impact of the untreated sewage dumping into the bay.

Guanabara Bay is a very heterogeneous enviro-nment, therefore, more sediment cores should be taken from various other regions within the bay in order to understand the flux of heavy metal into this water body. The studied area was always considered as a non-impacted area of the bay, been considered a "clean" zone inside the bay. However, these preliminary results highlight the extent of the environmental degradation experienced in Guanabara Bay as a whole in the last few decades. These results also correlated with data from other research that have also considered Guanabara Bay to be one of the most impacted coastal environments in Brazil.

This work was supported financially by Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)/Brazil.

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Patchineelam SM, Kjerfve B and Gardener RL. 1999. A preliminary sediment budget for the Winyah Bay estuary, South Carolina, USA. Mar Geol 162: 133-144.
Patchineelam SR and Smoak JM. 1999. Sediment accumu-lation rates along the inner eastern Brazilian continental shelf. Geo-Marine Letters 19: 196-201.
Peixoto TCS, Oliveira GH and Patchineelam SR. 2005. Geocronologia recente de uma lagoa costeira alterada, RJ. In: II Congr. Bras. Oceanografia. Vitória. Resumos. Vitória.
Rebello AL, Haekel W, Moreira I, Santelli R and Schroder F. 1986. The Fate of Heavy Metals in an Estuarine Tropical System. Elsevier Science. Mar Chem 18: 215-225.
Ridgway J and Shimmield G. 2002. Estuaries as repositories of historical contamination and their impact on shelf seas. Estuar Coast Shelf Sci 55: 903-928.
Robbins JA and Edgington DN. 1975. Determination of recent sedimentation rates in Lake Michigan using 210Pb and 137Cs. Geochim. Cosmochim Acta 39: 285-304.
Robbins JA and Herche LR. 1993. Models and uncertainty in 210Pb dating of sediments. Verh Int Ver Limnol 25: 217-222.
Ruiz-Fernández AC and Hillaire-Marcel C. 2009. 210Pb-derived ages for the reconstruction of terrestrial contaminant history into the Mexican Pacific coast: Potential and limitations. Mar Poll Bul 59: 134-145.
Sanchez-Cabeza J and Druffel ERM. 2009. Environmental records of anthropogenic impacts on coastal ecosystems: an introduction. Mar Poll Bul 59: 87-90.
Sanders CJ, Santos IR, Silva-Filho EV and Patchineelam SR. 2006. Mercury flux to estuarine sediments, derived from Pb-210 and Cs-137 geochronologies (Guaratuba Bay, Brazil). Mar Poll Bul 52: 1085-1089.
Sharma P, Gardner LR, Moore WS and Bollinger MS. 1987. Sedimentation and bioturbation in a salt marsh as revealed by 210Pb, 137Cs and 7Be studies. Limnol Oceanogr 32: 313-326.
Simões Filho FFL. 1993. A Hidrodinâmica de Particulados em Planícies de Inundação: Um Estudo Sobre as Taxas de Sedimentação de Lagoas Marginais do Rio Mogi-Guaçú. Estação Ecológica de Jataí (Luiz Antônio - SP). MSc. Dissertation. Universidade de São Carlos. São Carlos, SP , 109 p. (Unpublished).
Smith JN. 2001. Why should we believe 210Pb sediment geochronologies?, J Environ Radioac 55: 121-123.
Turner LJ and Delorme LD. 1996. Assessment of 210Pb data from Canadian lakes using the CIC and CRS models. Environ Geol 28: 78-87.
Vaalgamaa S. 2004. The effect of urbanisation on Laajalahti Bay, Helsinki City, as reflected by sediment geochemistry. Mar Poll Bul 48: 650-662.
Valette-Silver N. 1992. Historical Reconstruction of Contamination Using Sediment Cores: A Review. NOAA Technical Memorandum NOS/ORCA 65, 44 p.
Vandenberg C and Rebello AH. 1986. Organic-copper interactions in Guanabara Bay, Brazil - an electrochemical study of copper complexation by dissolved organic material in a tropical bay. Sci Total environ 58(1-2): 37-45.
Vilela CG, Batista DS, Baptista Neto JA, Crapez M and McAlister JJ. 2004. Benthonic Foraminifera distribution in a high polluted sediment from Niterói Harbour (Guanabara Bay), Rio de Janeiro, Brazil. An Acad Bras Cienc 76: 1-11.
Zimmerman AR and Canuel EA. 2000. A geochemical record of eutrophication and anoxia in Chesapeake Bay sediments: anthropogenic influence on organic matter composition. Mar Chem 69: 117-137.

Publication Dates

Publication in this collection
22 Oct 2013
Date of issue
2013

History

Received
31 Dec 2012
Accepted
03 Apr 2013

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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[63] Vandenberg C and Rebello AH. 1986. Organic-copper interactions in Guanabara Bay, Brazil - an electrochemical study of copper complexation by dissolved organic material in a tropical bay. Sci Total environ 58(1-2): 37-45.

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Author	Local	Flux of OrgC (g.m^-2.year^-1)
This study	Guanabara Bay, RJ	76 - 370
Carreira 2000	Guanabara Bay, RJ	22 - 272
Twilley 1992 apud Alongi et al. 2001	Mangroves from several countries.	99.7
Zimmerman and Canuel 2000	ChesaPeake Bay, EUA	46 - 165 (estimate)
Alongi et al. 2001	South of Thailand	183 - 281
Brunskill et al. 2002	Herbert River, Australia	26 - 336
Gordon and Goñi 2004	Mississipi Delta, EUA	54

	[PS]	t_i	t_e	FSC	EOS	ERI	RBB
Exp.	[PS]	t_i	t_e	FSC	EOS	ERI	RBB
1	-	-	-	11.72 ± 0.63	24.53 ± 0.94	26.36 ± 0.95	30.39 ± 1.69
2	+	-	-	15.14 ± 2.50	39.57 ± 0.66	35.19 ± 0.99	38.13 ± 1.03
3	-	+	-	8.79 ± 1.61	36.25 ± 0.59	36.05 ± 1.60	41.11 ± 1.21
4	+	+	-	17.96 ± 0.84	49.65 ± 1.06	52.23 ± 1.77	57.06 ± 1.21
5	-	-	+	7.76 ± 1.69	26.54 ± 0.21	26.73 ± 1.09	28.79 ± 0.85
6	+	-	+	15.95 ± 1.97	33.07 ± 1.49	36.34 ± 1.69	37.27 ± 1.48
7	-	+	+	8.15 ± 0.54	36.62 ± 0.32	35.89 ± 1.42	40.29 ± 1.04
8	+	+	+	18.20 ± 1.81	51.84 ± 1.09	56.03 ± 1.24	61.23 ± 0.53

Brasil