International Journal on Advanced Science, Engineering and Information Technology

This research's main objective is to delineate areas with a high concentration of "pollutant" elements that imply a risk for the ecosystem and inhabitants' health in the Cordillera Real, south of Ecuador. To this end, a survey was carried out applying statistical analysis of the data. Specifically, the method of ordinary Kriging and Lepeltier is used to sort the data in populations according to their concentration. Previously, the information was compared with national (TULAS) and international regulations (Environmental Canada). These metals' spatial distribution is shown in concentration maps for each element (Hg, Pb, Zn, As, and Cu), where the potential villages exposed to these anomalies are displayed. In this sense, the samples' chemical digestion was conducted to quantify the atomic emission technique's before-mentioned pollutants' concentration. It was also correlated with geology, mineral occurrences, and metallogeny evidence to conclude that Pb and Zn anomalies are related to San Lucas granodiorite's intrusion, whereas Cu and Hg with local mineralization of sulfides, and as may be with domestic and industrial discharges. Finally, even though the anomalous concentrations of metallic elements were found to be characteristic of the lithology, cautions should be taken to safeguard the health of people and agriculture because there is evidence of elements such as As and Hg bioaccumulation in species that are part of the food chain.

Anomaly; bioaccumulation; Lepeltier; Kriging; correlation; geology; watershed; mineralization; pollutant.

Trouw. R. Cuatro cortes por la faja metamórfica de la Cordillera Real. Ecuador. Guayaquil- Ecuador: Escuela Politécnica del Litoral.. 1976.

Litherland. M.. J. A. Aspden. y R. A. Jemielita. The Metamorphic Belts of Ecuador: Overseas Memoir of the British Geological Survey. Keyworth. 1994.

Jemielita. R. y Bolaños. J. Mineralización. potencial mineral y metalogénesis de la Cordillera Real del Ecuador. Quito-Ecuador: CODIGEM Misión Británica. 1993.

Izquierdo. O. «Estudio Geodinámico de la Cuenca Intrammontañosa cenozoica de Loja (Sur del Ecuador). Tesis de ingeniería no publicada.» Quito. Ecuador. 1991.

Hungerbühler. D.. Steinmann. M.. Winkler. W.. Seward. D.. Egüez. A.. Peterson. D.. Helg.U. y Hammer. C. Neogene Stratigraphy and Andean geodynamics of southern Ecuador.Earth-Science Reviews. p. 75-124. 2002.

Correa. C. «Análisis de la susceptibilidad de los fenómenos de remoción en masa de la carretera Loja-Zamora.» Tesis de Grado. Facultad de Geología y Petróleos. Escuela Politécnica Nacional. Quito. Ecuador. 2007.

Zhao. G. et al.. Distribution and contamination of heavy metals in surface sediments of the Daya Bay and adjacent shelf. China. Marine Pollution Bulletin (2016)

Ahmad. K. et al.. Occurrence. source identification and potential risj evaluation of heavy metals in sediments of the Hunza River and its tributaries. Gilgit-Baltistan. Environmental Technology & Innovation 18 (2020)

Lin. X. et al.. Geochemical patterns of Cu. Au. Pb and Zn in stream sediments from Tongling of East China: Compositional and geostatistical insights. Journal of Geochemial Exploration 210 (2020)

Amrit Kumar. et al.. Mapping spatial distribution of traffic induced criteria pollutants and associated health risks using kriging interpolation tool in Delhi. Journal of Transport & Health. 18 (2020). doi.org/10.1016/j.jth.2020.100879.

Shafie. N. et al.. Geoaccumulation and distribution of heavy metals in the urban river sediment. International Journal of Sediment Research. Vol. 29. N°. 3 (2014)

Sanjoy Shil. and Umesh Kumar Singh. Health risk assessment and spatial variations of dissolved heavy metals and metalloids in a tropical river basin system. Ecological Indicators. 106 (2019). doi.org/10.1016/j.ecolind.2019.105

Kyeonghwan Kang. et al.. Modified screening-based Kriging method with cross validation and application to engineering design. Applied Mathematical Modelling. 70 (2019). doi.org/10.1016/j.apm.2019.01.030.

Mahyadin Mohammadpour. et al.. Geochemical distribution mapping by combining number-size multifractal model and multiple indicator kriging. Journal of Geochemical Exploration. 200 (2019). doi.org/10.1016/j.gexplo.2019.01.018.

Gia Pham. T.; et al.. Application of Ordinary Kriging and Regression Kriging Method for Soil Properties Mapping in Hilly Region of Central Vietnam. Geo-Information. 147 (2019). doi.org/10.3390/ijgi8030147

Yarahmadi. S.. Ansari. M.. Ecological risk assessment of heavy metals (Zn. Cr. Pb. As and Cu) in sediments of Dohezar River. North of Iran. Tonekabon city. Acta Ecologica Sinica (2016)

Sandeep Kumar. et al.. Hazardous heavy metals contamination of vegetables and food chain: Role of sustainable remediation approaches - A review. Environmental Research. 179 (2019). doi.org/10.1016/j.envres.2019.108792.

El-Sorogy. A. et al.. Distribution. source. contamination. and ecological risk status of heavy metals in the Red Sea-Gulf of Aqaba coastal sediements. Saudi Arabia. Marine Pollution Bulletin 158 (2020)

Tahril. T.. et al.. Profile of metals Fe in lay ecosystem using ICP-OES in Donggala District. Indonesia. Current Chemistry Letters. 9 (2020). 10.5267/j.ccl.2019.11.001

Nakić. Z. et al.. Ambient Background Values of Selected Chemical Substances in Four Groundwater Bodies in the Pannonian Region of Croatia. Water. 12 (2020). doi.org/10.3390/w12102671

TULAS. «Texto unificado de legislación ambiental.» Quito. Ecuador. 2007.

Yang. P. G.. Mao. R.. Shao. H.. Gao. Y. The spatial variability of heavy metal distribution in the suburban farmland of Taihang Piedmont Plain. China. C.R. Biologies 332 (2009)

Sahoo. P.K. et al.. Regional-scale mapping for determining geochemical background values in souls of the Itacaiúnas River Basin. Brazil: The use of compositional data analysis. Geoderma 376 (2020)

Kabata-Pendias. A. Soil-plant transfe of trace elements- an environmental issue. Geoderma 122 (2004)

Cuculic. V. et al.. Natural and anthropogenic sources of Hg. Cd. P. Cu and Zn in seawater and sediment of Mljet National Park. Croatia. Estuarine. Coastal and Shelf Science 81 (2009)

Kabata-Pendias. A.. Pendias. H. Trace Elements in Soils and Plants. 3rd ed. CRC Press. Boca Ratón. Fl. (2001)

Akomaye. A.. & Unimuyi. U.. Concentration of Heavy Metals (Cd. Co. Cr. & Fe) in Soil and Edible Vegetables in Obudu Urban Area of Cross River State. Nigeria. Chemical Science International Journal. 27 (20191). doi.org/10.9734/CSJI/2019/v27i130105

Awe. A. et al.. Occurrence and probabilistic risk assessment of PAHs in water and sediment samples of the Diep River. South Africa. Heliyon 6 (2020)

Ruiz-Pico. A. et al.. Hydrochemical characterization of groundwater in the Loja Basin (Ecuador). Applied Geochemistry 104 (2019) 1–9

Lorenzo Morroni. et al.. Integrated characterization and risk management of marine sediments: The case study of the industrialized Bagnoli area (Naples. Italy). Marine Environmental Research. 160 (2020). doi.org/10.1016/j.marenvres.2020.104984.

Shunan Zheng. et al. Human health risk assessment of heavy metals in soil and food crops in the Pearl River Delta urban agglomeration of China. Food Chemistry. 316 (2020). doi.org/10.1016/j.foodchem.2020.126213.

Yuezhao Li. et al.. Source apportionment and source-oriented risk assessment of heavy metals in the sediments of an urban river-lake system. Science of The Total Environment. 737 (2020). doi.org/10.1016/j.scitotenv.2020.140310.

Rostami. A.A.. et al. Evaluation of geostatistical techniques and their hybrid in modelling of groundwater quality index in the Marand Plain in Iran. Environ Sci Pollut Res 26. 34993–35009 (2019). doi.org/10.1007/s11356-019-06591-z

Linnik. V.G. et al. Spatial distribution of heavy metals in soils of the flood plain of the Seversky Donets River (Russia) based on geostatistical methods. Environ Geochem Health (2020). doi.org/10.1007/s10653-020-00688-y

Zakir. H. M.. et al.. Health Risk Assessment of Heavy Metal Intake of Common Fishes Available in the Brahmaputra River of Bangladesh. Archives of Current Research International. 19 (2019). doi.org/10.9734/acri/2019/v19i230153