Next Article in Journal
Advancements, Challenges, and Future Directions in Aquatic Life Criteria Research in China
Next Article in Special Issue
Revisiting Genetic Influence on Mercury Exposure and Intoxication in Humans: A Scoping Review
Previous Article in Journal
Effects of Transporter Inhibitors and Chemical Analogs on the Uptake of Antimonite and Antimonate by Boehmeria nivea L.
Previous Article in Special Issue
Assessment of Anti-Alzheimer Pursuit of Jambolan Fruit Extract and/or Choline against AlCl3 Toxicity in Rats
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Toxics
Volume 11
Issue 10
10.3390/toxics11100861
toxics-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Environmental Geochemical Analysis in the Yanomami Indigenous Land, Mucajaí River Basin, State of Roraima, Brazil

by
Patricia Duringer Jacques
1,*,
Eduardo Paim Viglio
1 and
Daniel de Oliveira d’El Rei Pinto
2
1
CPRM—Geological Survey of Brazil, Rio de Janeiro 22.290-255, Brazil
2
Habitat Geo and Fundação Oswaldo Cruz, Rio de Janeiro 22.290-255, Brazil
*
Author to whom correspondence should be addressed.
Toxics 2023, 11(10), 861; https://doi.org/10.3390/toxics11100861
Submission received: 7 July 2023 / Revised: 19 September 2023 / Accepted: 22 September 2023 / Published: 14 October 2023
(This article belongs to the Special Issue Environmental Pollutants, Neurocognitive Disorders and Other Health Outcomes in Autochthones Populations Worldwide)
Browse Figures
Versions Notes

Abstract

:
The Yanomami Indigenous Land in the Amazon has a long history of illegal artisanal gold mining, leading to concerns about mercury (Hg) contamination. This study has conducted a geochemical analysis to assess Hg contamination from these mining activities. Geological materials, including river water and stream sediments, were collected from 14 predetermined points based on the Geological Survey of Brazil’s methodology. The results revealed that water samples did not show Hg contamination above the limits set by the National Council of the Environment (Conama) Resolution 357. However, two stream sediment samples, particularly PJS009 and PJS010 collected from the Mucajaí River, exceeded the Conama Resolution 454’s limit of 0.17 mg/kg. A Hg content of 0.344 mg/kg was found in the sediment sample PJS009, the one collected further upstream in the Mucajaí River, and 1.386 mg/kg was found in sample PJS010, also in the Mucajaí River in the region shortly before the Fumaça Waterfall, indicating that the sediments of the Mucajaí River may be contaminated with Hg from the Fumaça Waterfall upstream.

1. Introduction

There is a long history of metal mining in Brazil, which has polluted geological materials such as sediments, waters, oceans, and soils. These geological materials can reflect anthropogenic contamination sources [1,2,3,4] from the Anthropocene Epoch [5,6], when the human race began altering the planet, including long-term global geologic processes, at an increasing rate. This is even the case in places that should be isolated, such as regions designated as indigenous land in the Amazon region.
Being the region with the greatest biodiversity on the planet, the Amazon Region is home to more than half of the indigenous peoples of Brazil. They have developed a traditional way of life, intrinsically marked by their relationship with the environment, provided by the abundance of natural resources.
Although there are marks in the landscape from settlements, structures for managing water and fishing, and small fires from the beginning of the Christian era, it was the contact with European civilization from the 16th century onwards that caused the man–nature relationship in the Amazon to change.
New pressures on the biome are related, among other factors, to population growth, the search for natural resources, the rise of the capitalism model, technological development, the increase in land value, and the expansion of the agricultural frontier [7,8]. Intense migratory flows created cities and municipalities and boosted old urban centers with the discovery of gold deposits in the region. Along with other sociospatial fronts and processes, mining contributed to occupying the demographic frontier and consolidating the regional space [9].
These pressures have been growing over the years. According to data from the MapBiomas Project [10], from 1985 to 2021, there was a loss of 44.16 million hectares of forest cover in the Amazon biome. On the other hand, in the same period, there was an increase of 44.52 million hectares of areas occupied by agricultural activities, 225,867 ha of urban areas, and 217,387 ha of areas occupied by mining in the Amazon.
Widespread in the region, mining has been developed in different territories and, unfortunately, indigenous lands did not escape this process. Artisanal mining (garimpo) in indigenous lands, in addition to being illegal, is marked by the indiscriminate use of mercury—a metal used to separate gold from sediments, causing serious impacts on the environment and human health. After its release into the environment, this metal undergoes several chemical transformations, being incorporated into the food chain and, thus, reaching humans and being able to cause, in addition to sensory and motor neurological problems, other serious illnesses. The presence of mercury in the food chain is especially harmful in the Amazon since fishing is an essential activity [11]. There is a wide range of exposure, with average levels of mercury in hair samples above 15 µg/g in several Amazonian communities, placing them among the highest levels reported in the world [12,13].
One of the most affected territories by illegal gold mining in the Amazon is the Yanomami Indigenous Land, a place that has seen an explosion in prospecting activity in recent years, based on data from the Mapbiomas project [10]. This data highlights that the area dedicated to this activity surpassed 650 hectares in 2019, reaching 920 and 1,556 hectares, respectively, in subsequent years. Despite the advances obtained with remote sensing methodologies for environmental monitoring in Brazil, some regional specificities are probably not detected in this analysis, as is the case for mining carried out on rafts routinely seen in several Amazonian water bodies. They are smaller than the spatial resolution of Landsat images (30 m) and also migrate easily via the great rivers of the region. This fact was corroborated during this field work when an illegal mining raft was observed to be active on the Mucajaí River (latitude 2.759953°; longitude -62.290173°—Geographical Coordinates/SIRGAS Horizontal Datum 2000), close to the Fumaça Waterfall. However, it was “imperceptible” in Landsat images and in many other images with spatial resolution.
Since 2016, there has been some accelerated growth according to data from the National Institute of Spatial Research (INPE) [13], including in the Yanomami Indigenous Lands, caused by illegal mining, which increased from 0.1 km2 in 2016 to 4.2 km2 in 2020. There was an interruption in the identification of artisanal mining between the years 1998 and 2015. This may be related to the limitations of identifying mining by remote management or even the fact that mining in the Yanomami Indigenous Land (IL) in the 1980s and 1990s took place in isolated spots in the Serra do Surucucu. Moreover, tracks were bombed by the federal government, and mining was extinguished in the area. The return in 2017 was due to newly discovered gold and tantalite in another region.
Overlapping data from the National Mining Agency (ANM) within the limits of the Yanomami territory and its immediate surroundings of 5 km reveal the existence of 624 mining processes in different phases, the majority of which (94%) are in the research requirements phase, which is the first step to start the whole mineral process.
According to research carried out in the geographic information system of the National Mining Agency (SIGMINE) [14], the most coveted substance is gold, with more than 700,000 hectares required in that spatial area for this metal of great market value. Despite gold being the main target of the mining sector in the region, cassiterite and tantalite also arouse great interest with a required area of over 320,000 hectares.
A study published by the Geological Survey of Brazil (SGB) [15] in 2017 produced the geochemical atlas of the state of Roraima for approximately 54 chemical elements based on the collection stations of river water, river sediments, and soils from 2011. Among them, 429 river sediment samples were collected throughout the state, with the exception of indigenous areas in the state (including the Mucajaí River Basin). In the case of sediment samples for Hg analysis, only 204 points out of the 429 collected (48%) had an Hg value above the detection limit. The minimum value detected was 0.005 mg/kg and the maximum value was 1.05 mg/kg, the latter recorded in the Jufari River Basin. In the geochemical atlas of the state of Roraima, around 10% of stream sediment samples and 30% of soil samples showed content above the crustal average for Hg (0.08 mg/kg). Unfortunately, there was no collection of samples in the area studied in this article.
Bearing in mind the impact of such prospecting activity on the health of the Yanomami indigenous people who live on the banks of the Mucajaí River, with a focus on exposure to mercury, this paper analyzes the geological material (river water and stream sediment) collected in the Hydrographic Basin of the Mucajaí River (Roraima, Brazil), in October 2022, using the methodology developed by the Geological Survey of Brazil for a low-density geochemical survey.
This work is part of a research project of the Oswaldo Cruz Foundation—FIOCRUZ, known as “Impact of mercury in protected areas and forest peoples in the Eastern Amazon: an integrated health-environment approach”, which obtained the authorization of Entry into Indigenous Land number 67/AAEP/PRES/2022 from the National Indian foundation—FUNAI on behalf of the coordinator of the Project, Dr. Paulo Cesar Basta, allowing 23 researchers to conduct multidisciplinary research.

2. Materials and Methods

2.1. Study Area and Sampling Points

The study area is located in the State of Roraima, Brazil, on the upper course of the Mucajaí River, where 14 sample points of geological material from the rivers (14 samples of river water and 14 samples of stream sediment from the banks) were collected, which were sent for laboratory analysis (Figure 1). Sampling points are described in Table 1.

2.2. Data Collection

Field materials and equipment used for the collection were as follows: (i) Tablet with an application for recording the sample data in the SGB/CPRM geochemistry database (point coordinates, physical–chemical parameters obtained by the probe and records made in loco by the researcher); (ii) probe (AquaRead multiparameter meter) for recording pH, temperature, dissolved oxygen, electrical conductivity, Eh, and turbidity; (iii) bucket, plastic beakers, disposable syringes without tips, 0.45 µm millipore filters, sterilized polyethylene tubes of 50 mL, 20 mL of nitric acid, thermal box to keep the samples under refrigeration after collection; (iv) striped plastic bags, insulating tape, and permanent marker pens for sample identification and storage; (v) water samples were placed in thermal boxes at an average temperature of 10 °C.
The sampling points were previously loaded on the tablet and on the GPS device (Garmin GPSmap 62sc model) and navigation was promoted along the Mucajaí River to the tributaries that were sampled. Upon reaching the previously programmed point, the multiparametric meter was turned on and the probe was placed inside the bucket with a water sample where data on temperature, turbidity, pH, dissolved oxygen, electrical conductivity, and salinity were measured (Figure 2A).
Water was collected using a syringe, removing water from the beaker, and attaching the filter to its tip. The water was then inserted into the previously identified polyethylene tube and the first 50 mL (anions) were filtered. (Figure 2B).
The process was repeated in a second 50 mL tube acidified with 10 drops of nitric acid and identified with red ribbons for cation analysis. A third collection was performed without a filter but with acidification of the samples (10 drops of nitric acid) for mercury analysis. They were identified with the name of the sample and the sampled river and kept in the thermal boxes.
The stream sediments collection was carried out on the chosen margins with a predominance of fine sediments. The finer sediments were collected and placed directly in the plastic bag when composed of clay. In the case of sandier sediments, these were sieved through a 20# sieve. Only the material that passed this sieving was collected. Each sample contains about 1 kg of fine material (Figure 2C).
The samples were recorded on the tablet, with numerous characteristics noted, such as the following: width of the river; depth; flow speed; water level; type of vegetation on the banks; water color; sediment color; sediment composition; collection margin; all physical-chemical records measured; coordinates and elevation obtained with GPS.

2.3. Laboratories

After collection, the water samples were sent to the Geological Survey of Brazil-CPRM laboratory, located in Manaus, Brazil (LAMIN—MA), and analyzed via ICP-OES (Atomic Emission Spectrometry with Plasma Source) for 27 cations (Al, As, B, Be, Ba, Ca, Co, Cd, Cu, Cr, Li, Fe, Hg, K, Mg, Mn, Mo, Na, Ni, Pb, Se, Si, Sb, Sn, Sr, Ti, V, and Zn) and via ionic chromatography for 7 anions (fluoride, chloride, bromide, nitrite, nitrate, sulfate, and phosphate). Atomic absorption analyses for total Hg (DMA-80) were also performed.
The stream sediment samples were previously dried in ovens at a low temperature (50 °C), homogenized, and sieved at 80#, the passer being crushed at 150#, and acqua regia was used for an acid attack of the sediment. Analyses were performed via ICP-OES or ICP-MS (Inductively Coupled Plasma Mass Spectrometry) for 53 elements (Ag, Al, As, Au, B, Ba, Be, Bi, Ca, Cd, Ce, Co, Cr, Cs, Cu, Fe, Ga, Ge, Hf, Hg, In, K, La, Li, Mg, Mn, Mo, Na, Ni, P, Pb, Pd, Pt, Rb, Re, S, Sb, Sc, Se, Sn, Sr, Ta, Te, Th, Ti, Tl, U, V, W, Y, Zn, and Zr).

2.4. Legal References Used

In Brazil, Conama (National Council of the Environment) is the official agency responsible for determining the limits and quality standards for water, soil, sediment, and effluents, defining the quality values for each.
The maximum permissible value for freshwater class I of Conama Resolution 357 of 17 March 2005 [16] or the groundwater parameters of Conama Resolution 396 of 2008 [17] was applied for the evaluation of water quality. The maximum value allowed by the Ministry of Health Ordinance No. 2914 of 2011 [18] can also be used. In the absence of indications, the prevention values (Threshold Effects Level—TEL) from the 2008 NOAA Screening Quick Reference Tables [19] or the Guidelines for drinking-water quality from the World Health Organization, WHO, from 2011 [20] were applied to the assessment of sediments’ quality.
For the bottom sediment samples, level 1 values for freshwater from Conama resolution 454 of 11 January 2012 [21] were used for dredged sediments or the TEL of NOAA—SQuiRT for inorganic solids in February 2008 [20].

3. Results

All water test results for Hg came out negative. However, in four samples, the values exceeded the limits set by Conama Resolution 357 for Fe (0.300 mg/L), and in one sample, they exceeded the limit for Al (0.100 mg/L). In terms of the physico–chemical parameters, one sample showed a conductivity value above the recommended limit of 100 µS/cm, and two samples exhibited extremely high turbidity values exceeding 1,000 NTU. The following elements—As, B, Be, Cd, Co, Cr, Cu, Hg, Li, Mo, Ni, Pb, Sb, Se, Sn, Ti, and V—were not detected in the water samples. On the other hand, the levels of elements Ba, Ca, K, Mg, Mn, Na, Si, Sr, and Zn either remained below the limits specified in the current resolutions or were very low.
The results can be seen in Table 2 and their statistical summary in Table 3.
Two sediment samples showed mercury levels above level 1 of Conama Resolution 454. Hg contents of 0.344 mg/kg were found in the sediment sample PJS009, the one collected further upstream in the Mucajaí River, and 1.386 mg/kg in sample PJS010, which was also collected in the Mucajaí River in the region shortly before the Fumaça Waterfall, indicating that the sediments of the Mucajaí River may be contaminated with Hg from Fumaça Waterfall upstream. The presence of Hg in lower concentrations was found in the samples from the Jacaré and Guximaí rivers (water sample numbers PJA005 and PJA007, respectively), indicating the presence of possible gold mines towards their headwaters. High values were found for Al (water sample PJA008) and Fe (water samples PJ004, PJA005, PJA006, and PJA007), and low values for As, Au, Ba, Be, Ca, Cd, Ce, Co, Cr, Cs, Cu, Ga, Ge, In, K, La, Li, Mg, Mn, Mo, Na, Ni, P, Pb, Rb, Sc, Sn, Sr, Th, Ti, U, V, W, Y, and Zn. The elements Ag, B, Bi, Hf, Nb, Pd, Pt, Re, S, Sb, Se, Ta, Te, Tl, and Zr were not detected.
The results can be seen in their statistical summary in Table 4 and in the results in Table 5.
Maps were generated for the elements Hg, Al, and Fe in sediment, which are shown in Figure 3, Figure 4, and Figure 5, respectively. In the region of influence of the sampled basins, a polygon was delimited within which a raster surface was generated that represents the probable spatial and mathematical variation in the concentrations of elements in the stream sediments. For Hg, the sampled basins were delimited, indicating those with the presence of Hg and the region of the Mucajaí River from Fumaça Waterfall upstream were still open (because we were prevented from collecting samples further upstream for safety reasons), with values above the legislation.
For Al (Figure 4) and Fe (Figure 5), maps interpolated in the ArcGIS 10.8.2 software using the IDW (Inverse Distance Weighted) method are presented.

4. Discussion

The high values of Al and Fe, in this work, are interpreted as a result of lateritization processes in the Amazon Region. Eroded materials from the rocks are carried to the river sediments. The entire Amazon region is affected by processes that concentrate metallic elements, mainly Fe, Al and Mn, in the horizons that develop lateritization processes, generating ferruginous, manganese and bauxite crusts. The physical weathering of these horizons carries these metals to the river, where they are deposited with the heaviest sediments and end up partly solubilized and incorporated into the water. It is normal for values above those defined by the Brazilian legislation to occur in Amazonian waters for Al and Fe.
The comparison of the distribution patterns and grades of Hg obtained by the SGB’s study Geochemical Atlas of the State of Roraima and the ones obtained by this present study show a similarity among the number of samples below the detectable level (about 50%) and also with 14% (two of the 14 samples) with levels above the crustal average.
The origin of Hg in the region deserves more detailed investigations to try to define the origin of the enrichment of Hg in these sediments. Mercury is a transition metal, dense, highly volatile, which rarely occurs free in nature and is liquid under room temperature conditions and the known ore mineral is cinnabar (HgS), whose main deposits are found in Spain [22]. There are no cinnabar mines in Brazil and in the Amazon region there is no occurrence of Hg. Therefore, the possibility of the origin of high levels of Hg in the sediments of the state of Roraima and the area of the watershed of the Mucajaí River is that it is anthropic contamination, arising from the activity of illegal mining, which uses Hg to amalgamate gold in prospecting and mining.
Part of the metallic mercury may be converted to methylmercury via the action of microorganisms that live in river sediment [23]. Studies carried out in 2021 by Crespo-López et al. [24] demonstrate that there are methanogenic bacteria in two large dams in the Amazon (Tucurí and Balbina), which promote the methylation of Hg. At the bottom of the lakes of these dams, there are favorable conditions for the existence of these bacteria, which allow the entry of MeHg into the food chain. According to the same study, methanogenic bacteria can transform Hg into MeHg both from water and directly from sediment. There are contaminated people and contaminated fish around the dams, downstream, and in regions quite far from the artisanal mining region.
In the Mucajaí River Basin, methylmercury exists and is incorporated by aquatic biota with higher concentrations for organisms at the top of the food chain. Many of these organisms are part of the traditional diet of the Amazonian population, especially in indigenous communities, where access to other food resources is reduced.
Several studies in the region point to the presence of methylmercury at levels higher than those recommended by FAO/WHO [25]. As an example of this scenario, a study conducted by de Vasconcelos et al. 2021 [26] reveals a prevalence of methylmercury contamination (MeHg ≥ 0.5 µg/g) of 53% of fish analyzed in the lower Rio Mucajaí.
Anthropogenic mercury contamination, especially in the Amazon region, poses a great risk to human health. The consumption of contaminated fish can cause various health effects. Specifically in the Amazon, cognitive skills loss, psychomotor alterations, and mental development problems were observed in children exposed during the first months of the prenatal period [27]. In adults, symptoms such as depression, aggressiveness, insomnia, motor coordination problems, and visual capacity are commonly reported due to chronic exposure to mercury [27,28].

5. Conclusions

The results obtained show the existence of mercury in the bottom sediment of part of the Mucajaí, Jacaré, and Guximaí rivers. The high values above those allowed by Conama 454 are found close to Fumaça Waterfall, and also the indigenous community of Pewau, probably coming from the mines in Alto Mucajaí, according to data from MapBiomass [10]. Hg beads are heavy and are usually transported to the bottom of the main channel. The sudden break in the water flow immediately above Fumaça Waterfall must be the cause of the high concentration found just before it.
The absence of Hg in the surface water sampled indicates that there are no active processes in the region that promote the solubilization of Hg, allowing the passage of Hg found in the sediment to the water. If methylated Hg is present in the food chain, it is necessary to carry out a specific study to describe and understand the processes operating at the sediment–water interface at the bottom of the river that promote this methylation. But it is possible that the region of quiet waters caused by the Fumaça Waterfall allows the existence of bacteria that cause the methylation of Hg directly from the sediment, allowing its entry into the food chain.
The next stage of the study should include the integration of the geological material with the biological material collected in the study area for the evaluation of human contamination via the contamination of fish and hair samples from local communities, especially the communities close to points PJS0010 and PJS0011, Pewau and Thoribi indigenous communities.
Based on the absence of cinnabar (ore mineral of Hg) and the fact that in the field, during the sample collection in the field, illegal mining dredgers were found in the Mucajaí River, it can be deduced that the contamination of the river sediment samples is of anthropic origin caused by illegal mining, as a consequence of the use of amalgams for gold extraction.

Author Contributions

Methodology, P.D.J., E.P.V. and D.d.O.d.R.P.; Investigation, P.D.J., E.P.V. and D.d.O.d.R.P. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by CPRM—Geological Survey of Brazil and Fundação Oswaldo Cruz.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The geochemical results mentioned in this article can be found in GeoSGB, a database of the Geological Survey of Brazil at http://www.sgb.org.br (accessed on 31 October 2022), or requested from the authors by email.

Acknowledgments

Special thanks to researchers from Fundação Oswaldo Cruz, mainly to Paulo Basta, Project Chief, and researchers from the Geological Survey of Brazil—CPRM.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Doufexi, M.; Gamvroula, D.E.; Alexakis, D.E. Elements’ Content in Stream Sediment and Wildfire Ash of Suburban Areas in West Attica (Greece). Water 2022, 14, 310. [Google Scholar] [CrossRef]
  2. Alexakis, D.E. Diagnosis of stream sediment quality and assessment of toxic element contamination sources in East Attica, Greece. Environ. Earth Sci. 2011, 63, 1369–1383. [Google Scholar] [CrossRef]
  3. Ambrosino, M.; El-Saadani, Z.; Khatita, A.A.; Mingqi, W.; Palarea-Albaladejo, J.; Cicchella, D. Geochemical Speciation, Ecological Risk and Assessment of Main Sources of Potentially Toxic Elements (PTEs) in Stream Sediments from Nile River in Egypt. Water 2023, 15, 2308. [Google Scholar] [CrossRef]
  4. Melfi, A.J.; Forti, C. Estudo do Ciclo de Mercúrio no Ecossistema da Floresta Amazônica: Avaliação do Impacto da Mineração de ouro com Utilização de Mercúrio. Relatório Científico Final PADCT/CIAMB—CNPq No 620375/92.2. Edição Revisada em 2019. Available online: http://mtc-m21b.sid.inpe.br/col/sid.inpe.br/mtc-m21b/2019/10.04.14.36/doc/Relat-Hg-2019_datapaper.pdf (accessed on 6 July 2023).
  5. Steffen, W.P.; Crutzen, P.J.; McNeill, J.R. The Anthropocene: Are Humans Now Overwhelming the Great Forces of Nature? In Crutzen and the Anthropocene: A New Epoch in Earth’s History 2021. The Anthropocene: Politik—Economics—Society—Science; Benner, S., Lax, G., Crutzen, P.J., Pöschl, U., Lelieveld, J., Brauch, H.G., Paul, J., Eds.; Springer: Cham, Switzerland, 2007; Volume 1. [Google Scholar] [CrossRef]
  6. Waters, C.N.; Zalasiewicz, J.; Summerhayes, C.; Barnosky, A.D.; Poirier, C.; Gałuszka, A.; Cearreta, A.; Edgeworth, M.; Ellis, E.C.; Ellis, M.; et al. The Anthropocene is functionally and stratigraphically distinct from the Holocene. Science 2016, 351, aad2622. [Google Scholar] [CrossRef] [PubMed]
  7. Diegues, A. A Dinâmica Social do Desmatamento na Amazônia: Populações e Modos de Vida em Rondônia e Sudeste do Pará; UNRISD: São Paulo, Brazil; USP: North Bethesda, MD, USA; NUPAB: Cincinnati, OH, USA, 1993. [Google Scholar]
  8. Margulis, S. Causas do Desmatamento da Amazônia Brasileira; Banco Mundial: Brasília, Brazil, 2003. [Google Scholar]
  9. Wanderley, L. Geografia do Ouro na Amazônia Brasileira: Uma Análise a Partir da Porção Meridional. Ph.D. Thesis, Universidade Federal do Rio de Janeiro, Rio de Janeiro, Brazil, 2015. [Google Scholar]
  10. Mapbiomas. Coleção 7 da Série Anual de uso e Cobertura da Terra do Brasil. Available online: https://mapbiomas.org/ (accessed on 31 October 2022).
  11. Basta, P.C.; Viana, P.V.S.; Vasconcellos, A.C.S.; Périssé, A.R.S.; Hofer, C.B.; Paiva, N.S.; Kempton, J.W.; Ciampi De Andrade, D.; Oliveira, R.A.A.; Achatz, R.W.; et al. Mercury exposure in Munduruku indigenous communities from Brazilian Amazon: Methodological background and an overview of the principal results. Int. J. Environ. Res. Public Health 2021, 18, 9222. [Google Scholar] [PubMed]
  12. Passos, C.J.S.; Mergler, D. Human mercury exposure and adverse health effects in the Amazon: A review. Cad. Saúde Pública 2008, 24, s503–s520. [Google Scholar] [CrossRef] [PubMed]
  13. Mataveli, G.; Chaves, M.; Guerrero, J.; Escobar-Silva, E.V.; Conceição, K.; Oliveira, G. Mining Is a Growing Threat within Indigenous Lands of the Brazilian Amazon. Remote Sens. 2022, 14, 4092. [Google Scholar] [CrossRef]
  14. SIGMINE. Available online: https://geo.anm.gov.br/portal/apps/webappviewer/index.html?id=6a8f5ccc4b6a4c2bba79759aa952d908 (accessed on 31 March 2023).
  15. Conselho Nacional do Meio Ambiente. Resolução no 357, de 17 de março de 2005. Dispõe sobre a Classificação dos Corpos de água e Diretrizes Ambientais para o seu Enquadramento, bem como Estabelece as Condições e Padrões de Lançamento de Efluentes e dá Outras Providências; Diário Oficial da União: Seção 1, Brasília, DF, ano 142, n. 53; Conselho Nacional do Meio Ambiente: Brasília, Brazil, 2005; pp. 58–63. [Google Scholar]
  16. Conselho Nacional do Meio Ambiente. Resolução no 396, de 3 de Abril de 2008. Dispõe Sobre a Classificação e Diretrizes Ambientais Para o Enquadramento das Águas Subterrâneas e dá Outras Providências; Diário Oficial da União: Seção 1, Brasília, DF, ano 145, n. 66; Conselho Nacional do Meio Ambiente: Brasília, Brazil, 2008; pp. 64–68. [Google Scholar]
  17. Conselho Nacional do Meio Ambiente. Resolução no 454, de 01 de Novembro de 2012. Estabelece as Diretrizes Gerais e os Procedimentos Referenciais para o Gerenciamento do Material a ser Dragado em Águas sob Jurisdição Nacional; Diário Oficial da União: Seção 1, Brasília, DF, ano 149, n. 216; Conselho Nacional do Meio Ambiente: Brasília, Brazil, 2012; pp. 66–69. [Google Scholar]
  18. Buchman, M.F. Screening Quick Reference Tables. Seattle: NOAA. 2008; (NOAA OR & R Report 08-1). Available online: https://repository.library.noaa.gov/view/noaa/9327 (accessed on 28 November 2016).
  19. World Health Organization. Guidelines for Drinking Water Quality: Recommendations, 3rd ed.; WHO: Geneva, Switzerland, 2008; Available online: http://www.who.int/water_sanitation_health/dwq/fulltext.pdf (accessed on 13 September 2010).
  20. Freitas, A.F.; Marmos, J.L. Atlas Geoquímico do Estado de Roraima: Projeto Levantamento Geoquímico de Baixa Densidade do Estado de Roraima; CPRM: Recife, Brazil, 2017; 225p. [Google Scholar]
  21. Azevedo, F.A. Toxicologia do Mercúrio; Edição 1; Editora Rima: São Carlos, Brazil, 2003; 272p. [Google Scholar]
  22. Morel, F.M.; Kraepiel, A.M.; Amyot, M. The chemical cycle and bioaccumulation of mercury. Annu. Rev. Ecol. Syst. 1998, 29, 543–566. [Google Scholar]
  23. FAO/WHO. Joint FAO/WHO Expert Committee on Food Additives (JECFA); Report of the Tenth Section; FAO/WHO: Rotterdam, The Netherlands, 2016; Available online: http://www.fao.org/fao-who-codexalimentarius/sh-proxy/en/?lnk=1&url=https%253A%252F%252Fworkspace (accessed on 6 July 2023).
  24. de Vasconcellos, A.C.S.; Ferreira, S.R.B.; de Sousa, C.C.; de Oliveira, M.W.; de Oliveira Lima, M.; Basta, P.C. Health Risk Assessment Attributed to Consumption of Fish Contaminated with Mercury in the Rio Branco Basin, Roraima, Amazon, Brazil. Toxics 2022, 10, 516. [Google Scholar] [CrossRef] [PubMed]
  25. Marques, R.C.; Bernardi, J.V.E.; Cunha, M.P.L.; Dórea, J.G. Impact of organic mercury exposure and home delivery on neurodevelopment of Amazonian children. Int. J. Hyg. Environ. Health 2016, 219, 498–502. [Google Scholar] [PubMed]
  26. Reuben, A.; Frischtak, H.; Berky, A.; Ortiz, E.J.; Morales, A.M.; Hsu-Kim, H.; Pendergast, L.L.; Pan, W.K. Elevated Hair Mercury Levels Are Associated with Neurodevelopmental Deficits in Children Living Near Artisanal and Small-Scale Gold Mining in Peru. GeoHealth 2020, 4, e2019GH000222. [Google Scholar] [CrossRef]
  27. Crespo-López, M.; Augusto-Oliveira, M.; Lopes-Araújo, A.; Santos-Sacramento, L.; Takeda, P.; Macchi, B.; Nascimento, J.; Maia, C.; Lima, R.; Arrifano, G. Mercury: What can we learn from the Amazon? Environ. Int. 2021, 146, 106223. [Google Scholar] [CrossRef] [PubMed]
  28. Junior, J.M.F.C.; Da Silva Lima, A.A.; Junior, D.R.; Khoury, E.D.T.; Da Silva Souza, G.; De Lima Silveira, L.C.; Pinheiro, M.D.C.N. Manifestações emocionais e motoras de ribeirinhos expostos ao mercúrio na Amazônia. Rev. Bras. Epidemiol. 2017, 20, 212–224. [Google Scholar] [CrossRef]
Toxics 11 00861 g001
Figure 1. Area of studies and points of collection of a sample of geological material carried out (coordinate system Datum WGS 1984).
Figure 1. Area of studies and points of collection of a sample of geological material carried out (coordinate system Datum WGS 1984).
Toxics 11 00861 g001
Toxics 11 00861 g002
Figure 2. (A) Probe with some water measurements. (B) Water collection. (C) Stream sediment collection with sieving.
Figure 2. (A) Probe with some water measurements. (B) Water collection. (C) Stream sediment collection with sieving.
Toxics 11 00861 g002
Toxics 11 00861 g003
Figure 3. Map of mercury concentration in sediment (mg/kg) with the points collected from water in mg/L. Mercury was not detected in water, only in sediments (using the Conama 454 limits <0.0002 mg/L for water and 0.17 mg/kg for Hg). Coordinate system—Datum WGS 1984).
Figure 3. Map of mercury concentration in sediment (mg/kg) with the points collected from water in mg/L. Mercury was not detected in water, only in sediments (using the Conama 454 limits <0.0002 mg/L for water and 0.17 mg/kg for Hg). Coordinate system—Datum WGS 1984).
Toxics 11 00861 g003
Toxics 11 00861 g004
Figure 4. Map of aluminum concentration in sediment (mg/kg) with the points collected from water in mg/L. Both the water samples and the sediments have high values (using the Conama 357 limit of 0.100 mg/L for water). Coordinate system Datum WGS 1984.
Figure 4. Map of aluminum concentration in sediment (mg/kg) with the points collected from water in mg/L. Both the water samples and the sediments have high values (using the Conama 357 limit of 0.100 mg/L for water). Coordinate system Datum WGS 1984.
Toxics 11 00861 g004
Toxics 11 00861 g005
Figure 5. Map of iron concentration in sediment (mg/kg) with the points collected from water in mg/L. Both the water samples and the sediments have high values (using the Conama 357 limit of 0.300 mg/L for water). Coordinate system Datum WGS 1984.
Figure 5. Map of iron concentration in sediment (mg/kg) with the points collected from water in mg/L. Both the water samples and the sediments have high values (using the Conama 357 limit of 0.300 mg/L for water). Coordinate system Datum WGS 1984.
Toxics 11 00861 g005
Table 1. Geographical coordinates, elevation, and sampling date of sampling locations.
Table 1. Geographical coordinates, elevation, and sampling date of sampling locations.
Sample IDLat (N)Long (W)DateElevationLocation of Sampling Points
PJA0012.76584−62.2054410-October-2022185Left bank of Klokonai River, near the left bank of Mucajaí River
PJA0022.74977−62.1810010-October-2022186Left bank of Klaitabiu River
PJA0032.74438−62.0798310-October-2022182Left bank of Baixukuau River
PJA0042.73472−62.0115610-October-2022184Left bank of Sikaimabiu River
PJA0052.68764−61.9751010-October-2022171Right bank of Jacaré River
PJA0062.69650−61.9796110-October-2022176Right bank of the Mucajaí River. Sandbank abandoned by prospectors, with many pebbles.
PJA0072.75834−62.3022311-October-2022203Right bank of Guximai River, a tributary of the right bank of the Mucajaí River
PJA0082.76437−62.3151111-October-2022209Left bank of the Yalakapu Creek, a tributary of the left bank of the Mucajaí River
PJA0092.78466−62.4054811-October-2022221Left bank of the Pewau River. Indigenous Village of Pewau
PJA0102.77879−62.3916111-October-2022212Upper Mucajaí River
PJA0112.76993−62.3409211-October-2022211Right bank of the Mucajaí River, near Fumaça Waterfall.
PJA0122.75605−62.2457111-October-2022189Left bank of the Mucajaí River
PJA0132.75697−62.2286912-October-2022200Left bank of the Maxthak-u River, a tributary of the left bank of the Mucajaí River.
PJA0142.75700−62.2216912-October-2022200Left bank of the Mucajaí River. Iasasi Indigenous Village
Table 2. Results obtained in water samples.
Table 2. Results obtained in water samples.
Physico–Chemical Parameters
Sample IDConductivity (µS/cm)Temp (°C)pHTurbidity (NTU)Eh (mV)TDS (mg/L)-
PJA0015724.906.4423.30−3.5037
PJA0026524.706.218.3047.4040
PJA0035626.206.2216.40−0.5036
PJA00482-------6.0515.1057.5052
PJA0057727.306.8030.40−119.7049
PJA0064727.507.061176.00−149.7031
PJA00711824.986.782016.00−16.1078
PJA0087024.006.4133.40−6.0044
PJA0094624.506.4416.708.6029
PJA0105326.606.73195.0015.5032
PJA0114926.306.46136.00−87.1031
PJA0124826.706.35176.00−47.6027
PJA0136325.006.536.5021.5042
PJA0144726.806.06209.0058.7031
Anions
Sample IDBromide
mg/L		Chloride
mg/L		Fluoride
mg/L		Phosphate
mg/L		Nitrate
mg/L		Nitrite
mg/L		Sulfate
mg/L
PJA0010.0053.92740.04270.0050.47020.0050.0782
PJA0020.0050.65410.06740.0050.46390.0050.005
PJA0030.0050.68850.05860.0050.49030.0050.0882
PJA0040.0050.79830.05730.0050.51320.0050.0653
PJA0050.0050.78150.07740.0050.6450.0050.1737
PJA0060.0050.56860.04390.0050.82430.0050.2050
PJA0070.0050.64660.03960.0050.62860.0050.0911
PJA0080.015050.79840.04260.0051.04620.01010.2494
PJA0090.0050.51710.03550.0050.47260.0050.0434
PJA0100.0050.48450.04570.0050.7280.0050.2221
PJA0110.0050.52980.03990.0050.70900.0050.2057
PJA0120.0050.50610.04340.0050.83780.0050.4135
PJA0130.0050.74590.07780.012750.36160.0050.1958
PJA0140.0050.79040.04440.0050.87830.0050.2568
Cations
Sample IDAl mg/LBa mg/LCa mg/LFe mg/LHg mg/LK mg/L
PJA0010.010.031.5070.1750.000251.696
PJA0020.010.051.9450.0740.000251.914
PJA0030.010.0421.4830.2170.000251.567
PJA0040.010.0622.2190.340.000251.419
PJA0050.010.0562.160.5280.000251.295
PJA0060.010.0211.4020.3040.000251.145
PJA0070.010.0291.6650.3160.000250.949
PJA0080.1260.0350.9810.2710.000251.655
PJA0090.0210.0050.5450.0960.000250.772
PJA0100.010.0120.7670.130.000250.792
PJA0110.0410.0140.6950.1870.000250.785
PJA0120.0230.0130.7890.1730.000250.74
PJA0130.010.032.4020.1970.000252.168
PJA0140.010.0051.7130.1130.000251.274
Sample IDMg mg/LMn mg/LNa mg/LSi mg/LSr mg/LZn mg/L
PJA0010.6740.0052.0787.2660.0250.018
PJA0021.3070.0242.92711.1020.030.011
PJA0030.9560.0122.2967.4730.0310.005
PJA0041.1440.023.27211.4420.0480.005
PJA0051.3380.032.5878.9960.0390.005
PJA0060.7930.0111.5876.0750.0250.005
PJA0070.8240.0191.5566.0150.0260.005
PJA0080.8220.0151.2454.5090.0210.005
PJA0090.2830.0111.0023.8590.0130.005
PJA0100.6420.0051.0123.2560.0130.005
PJA0110.5570.0051.1113.8010.0140.005
PJA0120.6630.0051.2193.7820.0160.005
PJA0130.8510.0123.79211.7480.0280.005
PJA0140.6390.0052.1597.7720.0150.005
Table 3. Statistical summary for water results (in mg/L).
Table 3. Statistical summary for water results (in mg/L).
Statistical Parameters for Water SamplesLegal References Parameters
ElementDetection LimitMeasures > LimitMeanMedianMaximumMinimumStd. Dv.PORT.MS 2914/2011Conama 357Conama 396WHO 2011
CationsAl (mg/L)0.00540.0220.01000.12600.01000.03120.20.10.2
As (mg/L)0.00010 0.010.010.010.01
B (mg/L)0.050 -0.50.52.4
Ba (mg/L)0.0005140.0290.02950.06200.00500.01850.70.70.70.7
Be (mg/L)0.00020 -0.040.004-
Ca (mg/L)0.05141.451.502.40200.550.61----
Cd (mg/L)0.00050 0.0050.0010.0050.003
Co (mg/L)0.00050 0.050.050.050.05
Cr (mg/L)0.00050 -0.05--
Cu (mg/L)0.0050 20.00922
Fe (mg/L)0.005140.2230.19200.52800.07400.1209.0.3.0.30.3-
Hg (mg/L)0.000090 ----
K (mg/L)0.01141.2981.28452.16800.74000.4610----
Li (mg/L)0.0010 -2.5--
Mg (mg/L)0.05140.8210.80751.33800.28300.2907----
Mn (mg/L)0.001140.0130.01150.03000.00500.00800.10.10.1-
Mo (mg/L)0.00050 --0.07-
Na (mg/L)0.05141.991.833.79201.000.90200-20050
Ni (mg/L)0.0010 0.070.0250.020.07
Pb (mg/L)0.00050 0.010.010.010.01
Sb (mg/L)0.00050 0.0050.0050.0050.02
Se (mg/L)0.0050 0.010.010.010.04
Si (mg/L)0.5146.9356.670511.74803.25602.9926----
Sn (mg/L)0.0010 ----
Sr (mg/L)0.001140.0250.02500.04800.01300.0104----
Ti (mg/L)0.0050 ----
V (mg/L)0.00050 -0.10.05-
Zn (mg/L)0.0520.0060.00500.01800.00500.003750.185-
AnionsBromide (mg/L)0.31 0.0151 ----
Chloride (mg/L)1140.890.673.930.480.88250250250
Fluoride (mg/L)0.3140.0510.04420.07790.03550.01411.51.41.51.5
Phosphate (mg/L)0.51 0.0128 ----
Nitrate
(mg/L)		0.22140.6480.63681.04630.36160.198210101050
Nitrite
(mg/L)		0.161 0.0101 1113
Sulfate (mg/L)1140.1640.1850.4140.0050.109250250250-
Physic-Chem ParametersConductivity (µS/cm)-1462.7156.50118.0046.0019.69-100--
DO (mg/L)-141.7281.672.671.210.44->2--
Temp. (°C)-1325.80626.2027.5024.001.16----
pH-146.4676.447.066.050.29-6 to 9--
Turbidity (NTU)-14289.86431.902016.006.50582.14----
Eh (mV)-6−15.786−2.0058.70−149.7063.96----
TDS (mg/L)-1439.92936.5078.0027.0013.33----
Table 4. Statistical description for stream sediment samples of the study area.
Table 4. Statistical description for stream sediment samples of the study area.
Statistical Parameters for Stream Sediments SamplesLegal References
Parameters
ElementDetection LimitMeasures > LimitMeanMedianMaximumMinimumStd. DvConama 454 (Level 1)NOAA SQuiRT 2008 (TEL)
Ag (mg/kg)0.010 --
Al (%)0.01140.1270.0990.3070.0330.088--
As (mg/kg)1100.0760.0750.240<LOD0.0725.95.9
Au (μg/kg)0.1145.9795.7507.0005.2000.596--
B (mg/kg)100 --
Ba (mg/kg)51422.83316.96053.4304.09016.745--
Be (mg/kg)0.180.1210.0550.670<LOD0.182--
Bi (mg/kg)0.020 --
Ca (%)0.01130.0130.0080.033<LOD0.012--
Cd (mg/kg)0.051 0.100 0.60.596
Ce (mg/kg)0.05117.6646.43519.430<LOD6.919--
Co (mg/kg)0.1142.1161.5156.1400.3901.657--
Cr (mg/kg)1145.0593.98010.7000.9603.37537.337.3
Cs (mg/kg)0.0590.2030.0950.530<LOD0.212--
Cu (mg/kg)0.5111.7361.4003.900<LOD1.35935.735.7
Fe (%)0.01140.3140.2350.7180.0690.218--
Ga (mg/kg)0.150.264<LOD1.600<LOD0.521--
Ge (mg/kg)0.1148.3577.40012.8005.9002.370--
Hf (mg/kg)0.050
Hg (mg/kg)0.0170.1320.0111.386<LOD0.3720.170.174
In (mg/kg)0.020 --
K (%)0.01140.0340.0240.0870.0010.028--
La (mg/kg)0.181.9071.2507.000<LOD2.347--
Li (mg/kg)1141.2001.0002.7000.2000.760--
Mg (%)0.01140.0400.0280.0970.0030.032--
Mn (mg/kg)51456.57939.950170.30016.20044.401--
Mo (mg/kg)0.051 0.025 --
Na (%)0.011 0.017 --
Nb (mg/kg)0.050 --
Ni (mg/kg)0.5141.6071.4003.3000.2001.0581818
P (mg/kg)501234.85729.5008 < LOD1 < LOD21.707--
Pb (mg/kg)0.2142.0281.8454.6100.4901.3823535
Pd (mg/kg)0.20 --
Pt (mg/kg)0.10 --
Rb (mg/kg)0.21 1.000 --
Re (mg/kg)0.10 --
S (%)0.010 --
Sb (mg/kg)0.050 --
Sc (mg/kg)0.1131.4931.2003.500<LOD1.001--
Se (mg/kg)10 --
Sn (mg/kg)0.31 0.100 --
Sr (mg/kg)0.5131.4571.0503.8000.2001.121--
Ta (mg/kg)0.050 --
Te (mg/kg)0.050 --
Th (mg/kg)0.11 0.500 --
Ti (%)0.01140.0080.0070.0170.0010.005--
Tl (mg/kg)0.020 --
U (mg/kg)0.05140.2780.2010.5690.0510.176--
V (mg/kg)1149.4267.11523.2702.2906.894--
W (mg/kg)0.11 0.100 --
Y (mg/kg)0.0590.7500.5002.920<LOD0.913--
Zn (mg/kg)175.3934.25013.000<LOD4.896123123
Zr (mg/kg)0.50 --
Table 5. Chemical analysis results of stream sediment samples of the studied area.
Table 5. Chemical analysis results of stream sediment samples of the studied area.
Sample IDAl (%)As (mg/kg)Au (mg/kg)Ba (mg/kg)Be (mg/kg)Ca (%)Cd (mg/kg)Ce (mg/kg)Co (mg/kg)Cr (mg/kg)
PJS0010.089<LOD5.20011.680<LOD0.008<LOD2.1900.7802.900
PJS0020.1370.0505.50021.5400.1300.0050.0258.0301.5505.420
PJS0030.210.0705.70046.1200.6700.031<LOD11.0903.4509.700
PJS0040.032<LOD5.8006.340<LOD0.001<LOD<LOD0.6901.390
PJS0050.1710.1307.00053.4300.2700.0120.10019.1106.1409.070
PJS0060.2490.2406.10043.5800.1700.031<LOD19.4304.0408.970
PJS0070.033<LOD6.0004.440<LOD<LOD<LOD<LOD0.6401.560
PJS0080.0990.0105.60014.1900.1300.007<LOD2.9000.8004.630
PJS0090.037<LOD5.5004.0900.0300.0010.025<LOD0.3900.960
PJS0100.1960.1305.70033.2400.2100.0260.0258.8003.4706.590
PJS0110.0450.1307.00011.660<LOD0.033<LOD15.3901.4802.380
PJS0120.0710.0806.20012.100<LOD0.0050.0253.1102.1403.230
PJS0130.3070.1105.50037.5200.0800.001<LOD12.4102.64010.700
PJS0140.0980.1206.90019.730<LOD0.018<LOD4.8401.4203.330
Sample IDCs (mg/kg)Cu (mg/kg)Fe (%)Ga (mg/kg)Ge (mg/kg)Hg (mg/kg)In (mg/kg)K (%)La (mg/kg)Li (mg/kg)
PJS0010.0700.8000.179<LOD8.000<LOD<LOD0.027<LOD0.600
PJS0020.2102.2000.344<LOD6.100<LOD<LOD0.0311.7001.100
PJS0030.5203.4000.6870.3009.000<LOD<LOD0.0862.0002.700
PJS004<LOD0.2500.105<LOD7.200<LOD<LOD0.008<LOD0.200
PJS0050.4403.2000.4850.40012.4000.022<LOD0.0454.4001.800
PJS0060.5303.5000.5181.6007.4000.0290.0100.0655.8001.800
PJS007<LOD0.2500.084<LOD5.9000.021<LOD0.004<LOD0.500
PJS0080.1101.3000.242<LOD11.200<LOD<LOD0.021<LOD1.400
PJS009<LOD<LOD0.068<LOD6.600<LOD<LOD0.001<LOD0.600
PJS0100.3802.5000.4070.1007.0000.344<LOD0.0662.0002.400
PJS0110.0250.8000.131<LOD12.8001.386<LOD0.0117.0000.800
PJS0120.0250.7000.191<LOD5.9000.027<LOD0.015<LOD0.500
PJS0130.4503.9000.71.3007.4000.0220.0100.0693.0001.500
PJS0140.0801.5000.22673<LOD10.100<LOD<LOD0.0200.8000.900
Sample IDMg (%)Mn (mg/kg)Mo (mg/kg)Na (%)Ni (mg/kg)P (mg/kg)Pb (mg/kg)Rb (mg/kg)Sc (mg/kg)Sn (mg/kg)
PJS0010.02518.600<LOD<LOD0.80022.0000.840<LOD0.800<LOD
PJS0020.03823.600<LOD<LOD1.50041.0002.160<LOD1.8000.050
PJS0030.097109.100<LOD<LOD3.30060.0003.0601.0002.2000.050
PJS0040.00837.900<LOD<LOD0.50015.0000.640<LOD0.900<LOD
PJS0050.046170.300<LOD<LOD2.60080.0004.610<LOD2.600<LOD
PJS0060.08486.100<LOD<LOD2.90066.0003.550<LOD3.0000.050
PJS0070.00818.500<LOD<LOD0.40010.0000.490<LOD0.800<LOD
PJS0080.02022.900<LOD<LOD1.00024.0001.380<LOD1.400<LOD
PJS0090.00316.200<LOD<LOD0.20010.0000.560<LOD<LOD<LOD
PJS0100.07892.800<LOD<LOD2.50038.0002.240<LOD1.400<LOD
PJS0110.01638.4000.0250.0170.90046.0001.850<LOD1.000<LOD
PJS0120.01765.100<LOD<LOD1.60033.0000.890<LOD0.800<LOD
PJS0130.08251.100<LOD<LOD3.00017.0004.280<LOD3.5000.100
PJS0140.03141.500<LOD<LOD1.30026.0001.840<LOD0.700<LOD
Sample IDSr (mg/kg)Th (mg/kg)Ti_%U (mg/kg)V (mg/kg)W (mg/kg)Y (mg/kg)Zn (mg/kg)
PJS0010.600<LOD0.0070.1774.990<LOD<LOD2.500
PJS0020.900<LOD0.0100.2979.990<LOD0.6607.000
PJS0033.800<LOD0.0160.46015.370<LOD1.0401 < LOD
PJS0040.400<LOD0.0020.0512.290<LOD<LOD<LOD
PJS0051.900<LOD0.0090.56917.370<LOD2.17011.000
PJS0063.200<LOD0.0130.54918.550<LOD2.92012.000
PJS0070.300<LOD0.0010.0732.570<LOD<LOD<LOD
PJS0081.200<LOD0.0050.1917.250<LOD<LOD<LOD
PJS0090.200<LOD0.0010.1782.610<LOD<LOD<LOD
PJS0102.700<LOD0.0130.34012.700<LOD1.29013.000
PJS0111.700<LOD0.0020.2033.810<LOD0.4402.500
PJS0120.800<LOD0.0040.1114.210<LOD0.0906.000
PJS0130.9000.5000.0160.49723.2700.1001.3309.000
PJS0141.800<LOD0.0050.1986.980<LOD0.5602.500
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Jacques, P.D.; Viglio, E.P.; de Oliveira d’El Rei Pinto, D. Environmental Geochemical Analysis in the Yanomami Indigenous Land, Mucajaí River Basin, State of Roraima, Brazil. Toxics 2023, 11, 861. https://doi.org/10.3390/toxics11100861

AMA Style

Jacques PD, Viglio EP, de Oliveira d’El Rei Pinto D. Environmental Geochemical Analysis in the Yanomami Indigenous Land, Mucajaí River Basin, State of Roraima, Brazil. Toxics. 2023; 11(10):861. https://doi.org/10.3390/toxics11100861

Chicago/Turabian Style

Jacques, Patricia Duringer, Eduardo Paim Viglio, and Daniel de Oliveira d’El Rei Pinto. 2023. "Environmental Geochemical Analysis in the Yanomami Indigenous Land, Mucajaí River Basin, State of Roraima, Brazil" Toxics 11, no. 10: 861. https://doi.org/10.3390/toxics11100861

APA Style

Jacques, P. D., Viglio, E. P., & de Oliveira d’El Rei Pinto, D. (2023). Environmental Geochemical Analysis in the Yanomami Indigenous Land, Mucajaí River Basin, State of Roraima, Brazil. Toxics, 11(10), 861. https://doi.org/10.3390/toxics11100861

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop