Browse

Journals By Subject

Life Sciences, Agriculture & Food
Chemistry
Medicine & Health
Materials Science
Mathematics & Physics
Electrical & Computer Science
Earth, Energy & Environment
Architecture & Civil Engineering
Education
Economics & Management
Humanities & Social Sciences
Multidisciplinary

Books

Publish Conference Abstract Books
Upcoming Conference Abstract Books
Published Conference Abstract Books
Publish Your Books
Upcoming Books
Published Books

Proceedings

Events

Events
Five Types of Conference Publications

Join

Join the Editorial Board
Become a Reviewer

Information

For Authors
For Reviewers
For Editors
For Conference Organizers
For Librarians
Article Processing Charges
Special Issue Guidelines
Editorial Process
Manuscript Transfers
Peer Review at SciencePG
Open Access
Copyright and License
Ethical Guidelines
| Peer-Reviewed

Heavy Metals in Paddy Soils of Brunei Darussalam and Their Relationship with Selected Soil Properties

Kyi Pyar Zin, L. H. Lim, J. M. R. Sarath Bandara, H. M. Thippeswamy
Published in International Journal of Environmental Monitoring and Analysis (Volume 5, Issue 3)
Received: 7 March 2017    Accepted: 23 March 2017    Published: 13 April 2017
Views:       Downloads:
Download PDF
Abstract

In Brunei Darussalam, available information of heavy metals in agricultural soils is sparse and hence a baseline study was carried out on soils in rice growing areas. In this study, trace elements as well as common soil characteristics were determined from twenty six of major rice fields such as Wasan, Limau Manis, Selapon and Lot Senkuang. Al, Fe, Mn and Cd were high in these areas however; Cu, Zn, Cr, Co, Ni and Pb were below safety limit of soil while Mn and Cd were above the permissible limit according to the WHO/CCME/European Union guidelines. The variations in metal concentrations in these samples are highly correlated to the acidic condition, organic matter and CEC of the paddy soils. The distributions of Al, Fe, Cu, Mn, Cd, Cr, Co, Pb were high at low pH. Cu, Zn, Cd, Ni and Pb showed positive correlation with organic matter while the quantities of Al, Fe, Mn, Cr and Co were negatively correlated. Correlation analyses showed that the Cd, Zn and Ni were associated with CEC while most of the metals were related to Al and Fe. The soils of the studied areas are extremely acidic with pH 3.0-4.6, and low in cations, CEC and available P, while having a high OM content. Low content of P was due to high amount of Al and Fe in these areas.

Published in International Journal of Environmental Monitoring and Analysis (Volume 5, Issue 3)
DOI 10.11648/j.ijema.20170503.11
Page(s) 64-72
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2024. Published by Science Publishing Group
Previous article
Keywords

Heavy Metals, Soil Acidity, Aifisols, Histosols, Vertisols

References
[1] Acosta, J. A., Martinez-Martinez, S., Faz, A. and Arocena, J., 2011. Accumulations of major and trace elements in particle size fractions of soils on eight different parent materials. Geoderma 161, 30-42.
[2] Adeniyi, A. A., Yusuf, K. O. and Okedeyi, O. O., 2008. Assessment of the exposure of two fish species to metals pollution in the Ogun river catchements, Ketty, Lagos, Nigeria. Environmental Monitoring and Assessment 137, 451-458.
[3] Akinnifesi, T. A., Asubiojo, O. I. and Amusan, A. A., 2006. Effects of fungicide residues on the physico-chemical characteristics of soils of a major cocoa-producing area of Nigeria. Sci. Total Environ 366, 876-879.
[4] Alkorta, I., Hernandez-Alica, J., Becerril, J. M., Amezaga, I., Albizu, I. and Garbisu, C., 2004. Recent findings on the phytoremediation of soils contaminated with environmentally toxic heavy metals and metalloids such as zinc, cadmium, lead and arsenic. Rev Environ SciNio/Tech 3, 71-90.
[5] Alloway, B. J., 1995. Heavy metals in soils. 2nd Ed. Blackie Academic &Professional An imprint of Chapman & Hall, UK.
[6] Andriesse, W. and van Mensvoort, M. F., 2002. Distribution and extent of acid sulphate soils. In: Lal R. (ed.), Encyclopedia of soil science, Marcel Dekker Inc., New York, pp. 1-6.
[7] Apokpodion, P. E., Lajide, L. and Aiyedanmi, A. F., 2013. Characterization of heavy metal fractions in agricultural soils using sequential extraction technique. World Journal of Agricultural Sciences 1, 45-52.
[8] Atafar, Z., Mesdaghinia, A., Nouri, J., Homaee, M., Yunesian, M., Ahamadimoghaddam, M. and Mahvi, A. H., 2010. Effect of fertilizer application on soil heavy metal concentration. Environmental Monitoring and Assessment 160, 83-89.
[9] ATSDR., 2004. Agency for Toxic Substances and Disease Registry. Toxicological Profile for cobalt. Atlanta, GA: U. S. Department of Health and Human Services, Public Health Service.
[10] Aydinalp, C. and Marinova, S., 2003. Distribution and forms of heavy metals in some agricultural soils. Polish Journal of Environmental Studies Vol.12 No.5, 629-633.
[11] Ayele, T., Ayana, M., Tanto, T., Asefa, D., 2014. Evaluating the Status of micronutrients under irrigated and rainfed agricultural soils in Abaya Chamo Lake Basin, South-west Ethiopia. Journal of Scientific Research and Reviews Vol.3 (1), 018-027.
[12] Bandara, J. M. R. S., Wijewardena, H. V. P., Bandara, Y. M. A. Y., Jayasooriya, R. G. P. T. and Rajapaksha, H., 2010a. Pollution of River Mahaweli and farmlands under irrigation by cadmium from agricultural inputs leading to a chronic renal failure epidemic among farmers in NCP, Sri Lanka. Environmental Geochemistry and Health doi: 10.1007/s10653-010-9344-4.
[13] Bandara, J. M. R. S., Wijewardena, H. V. P., Liyanege, J., Upul, M. A. and Bandara, J. M. U. A., 2010b. Chronic renal failure in Sri Lanka caused by elevated dietary cadmium: Trojan horse of the green revolution. Toxicology Letters 198, 33-39.
[14] Cakmak, D., Saljnikov, E., Mrvic, V., Jakovljevic, M., Marjanovic, Z., Sikiric, B. and Maksimovic, S., 2010. Soil properties and trace elements following 40 years of phosphate fertilization. J. Environ Qual 39, 541-547.
[15] Calvino, D. F., Suarez, J. A. R., Periago, E. L., Estevez, M. A. and Gandara, J. S., 2008. Copper content of soils and river sediments in a winegrowing area, and its distribution among soil or sediment components. Geoderma 145, 91-97.
[16] CCME, 2014. Canadian environmental soil quality guidelines. Canadian Council of Ministers of the Environment.www.ccme.ca/en/resources/canaidan-environmental-quality-guidelines.
[17] Cerqueira, B., Vega, F. A., Serra, C., Silva, L. F. O., Andrade, M. L., 2011. Time of flights secondary ion mass spectrometry and high-resolution transmission electron microscopy/energy dispersive spectrometry: A preliminary study of the distribution of Cu2+ and Cu2+/Pb2+ on a Bt horizon surfaces. J. Hazard. Mater 195, 422-431.
[18] Charman, P. E. V. and Hooper, M. M. 2000. Soil organic matter (SOM). In Charman, P. E. V., Murphy, B. W. eds. Soils: Their properties and management. 2nd Ed. Oxford University Press, pp. 260-270.
[19] Chinchmalatpure, A. R. B. L., Challa, O. and Sehgal, J., 2000. Available micronutrient status of soils on different parent materials and landforms in a micro- watershed of Wunna catchment near Nagpur (Maharashtra). Agropedology 10 (1), 53-58.
[20] Dharumarajan, S. and Singh, S. K., 2014. Variation of soil properties and phosphorus fractions in three cropping systems of lower indo-Gangetic alluvial plain. African Journal of Agricultural Research Vol.9 24, 187-1886.
[21] Diatta, J. B., 2008. Mutual Cu, Fe and Mn solubility control under differentiated soil moisture status. Journal of Elementology 13 (4), 473-489.
[22] Diatta, J. B., Witczak, R. and Skubiszewska, A. 2009. Zinc dynamics in an arable soil as affected by plant residues incorporation: agro environmental concern. Fresenius Environmental Bulletin 18 (10a), 1957-1962.
[23] EPA., 2007. Site contamination-acid sulfate soil materials. EPA Guidelines, Environmental Protection Act, 1-15.
[24] European Union., 2002. Heavy metals in wastes, European Commission on environment. http:// ec. europa. eu/ environment/waste/studies/pdf/heavy metals report.pdf.
[25] Fakhry, A., Osman, O., Ezzat, H. and Ibrahim, M., 2016. Spectroscopic analyses of soil samples outside Nile Delta of Egypt. SpectrochimicaActa Part A: Molecular and Bimolecular Spectroscopy Vol.168 (5), 244-252.
[26] Fältmarsch, R. M., Astrom, M. E. and Vuori, K. M., 2009. Environmental risks of metals mobilized from acid sulphate soils in Finland: a literature review. Boreal Environment Research 13, 444-456.
[27] Ghabbour, E. A., Davies, G., Ghali, N. K. and Mulligan, M. D., 2001. The effect of temperature on tight metal binding by peat and soil derived solid humic acids. Canadian Journal of Soil Science 81 (3), 331-336. 10.4141/S00-065.
[28] Goasvi, K., Sammut, J., Gifford, S. and Jankowski, J., 2004. Macro algal biomonitors of trace metal concentration in acid sulfate soil aquaculture ponds. Sci Total Env 25, 25-39.
[29] Gomez, M. I., Castro, H. E. and Pacheco, Y. W., 2005. Recovery and management of actual acid sulphate soils in Boyaca (Colombia). AgronomíaColombiana 23 (1), 128-135.
[30] Grealish, G., Fitzpatrick, R., Voase, A. R. and Hicks, W., 2008a. Brunei: Summary of acid sulfate soils. In Inland Acid Sulfate Soil Systems Across Australia (Eds. Rob Fitzpatrick and Paul Shand). pp. 301- 309. CRC LEME Open files Report No. 249. (Thematic Volume) CRC LEME, Perth, Australia.
[31] Grealish, G. J. and Fitzpatrick, R. W., 2013. Acid sulphate soil characterization in Negara Brunei Darussalam: a case study to inform management decisions. Soil Use and Management September 29, 432-444.
[32] Grealish, G. J., Ringrose-Voase, A. J., Fitzpatrick, R. W., Wong M. T. F. and Winston, E. C., 2008b. Soil fertility evaluation/advisory Service in Negara Brunei Darussalam Volume 1 – soils and land Suitability of the agricultural development areas’. Science Report 57/08. CSIRO Land and Water, Australia.
[33] Haliru, H. A., Ling, L. P. and Suhaiza, S. O., 2014. Heavy metal concentration levels in soil at Lake Geriyo irrigation site, Yola, Adamawa state, North Eastern Nigeria. International Journal of Environmental Monitoring and Analysis 2 (2), 106-111.
[34] Hernandez, L., Probst, A., Probst, J. and Ulrich, E., 2003. Heavy metal distribution in some French forest soils: evidence for atmospheric contamination. Sci Total Environ 312, 195-219.
[35] Hooda, P. S., 2010. Trace elements in soils. Wiley publication, pp. 596.
[36] IBM Statistics., 2012. SPSS Version 21. Property of IBM Corp. © Copyright IBM cooperation and its licensors 1989.
[37] Issaka, R. N., Senayah, J. K., Andoh-Mensah, E. and Ennin, S. A., 2012. Assessment of fertility status of soils supporting coconut (Cocusnucifera) cultivation in Western and central regions of Ghana. West African Journal of Applied Ecology Vol. 20 (1), 47-56.
[38] Jan, F. A., Ishaq, M., Khan, S., Ihasanullah, I., Ahmad, I. and Shakirullah, M. 2010. A comparative study of human health risks via consumption of food crops grown on wastewater irrigated soil (Peshawar) and relatively clean water irrigated soil (Lower Dir). J. Hazard. Mat 179, 612-621.
[39] Jones, C. and Jacobsen, J., 2009. Micronutrients: Cycling, testing and fertilizer recommendations. Nutrient management modules 7, #4449-7, Montana State University Extension Service, Bozeman, Montana.
[40] Kasa, E., Felix-Henningsen, P., Duering, R. A. and Gjoka, F., 2014. The occurrence of heavy metals in irrigated and non-irrigated arable soils, NW Albania. Environmental Monitoring and Assessment 186, 3595-3603.
[41] Kelepertzis, E., 2014. Accumulation of heavy metals in agricultural soils of Mediterranean: Insights from Argoloda basin, Peloponnese, Greece. Geoderma 221-222, 82-90.
[42] Khairiah, J., Tharmendren, M. S. M., Habibah, J., Zulkefly, H., Wan Kamal, W. I. and Ismail, B. S., 2012. Heavy metal content in paddy soils of Ketara, Besut, Terengganu, Malaysia. World Applied Sciences Journal 19 (2), 183-191.
[43] KyiPyarZin, Lim, L. H., ThippeswamyHoligeMallikarjunaiah. And SarathBandara, J. M. R., 2015. Chemical properties and phosphorus fractions in profiles of acid sulfate soils of major rice growing areas in Brunei Darussalam. Geoderma Regional 6 22-30.
[44] Lee, C. S. L., Li, X., Shi, W., Cheung, S. C. N. and Thornton, L. 2006. Metal contamination in urban, suburban and country park soils of Hong Kong: A study based on GIS and multivariate statistics. Sci. Total Environ Vol.356 (1-3), 45-61.
[45] Li, Y., Zhang, H., Chen, X., Tu, C., Luo, Y. and Christie, P. 2014. Distribution of heavy metals in soils of the Yellow River Delta: concentrations in different soil horizons and source identification. J Soils Sediments 14, 1158-1168.
[46] Liang, Q., Chen, H., Gong, Y., Fan, M., Yang, H., Lal, R. and Kuzyakov, Y., 2012. Effects of 15 years of manure and inorganic fertilizers on soil organic carbon fractions in a wheat-maize system in the North China Plain. Nutr. Cycl. Agroecosyst 92, 21-33.
[47] Magahud, J. C., Badayos, R. B., Sanchez, P. B. and Cruz, P. C. S., 2015. Levels and sources of potassium, calcium, sulfur, iron and manganese in major paddy soils of the Philippines. International Journal of Philippine Science and Technology Vol.8 No.2, 1-8.
[48] Manahan, S. E., 2003. Toxicological Chemistry and Biochemistry, CRC Press, Limited Liability Company (LLC) 3rd edition.
[49] Marzaioli, R., D’ Ascoli, R., De Pascale, R. A. and Rutigliano, F. A. 2010. Soil quality in a Mediterranean area of Southern Italy as related to different land use types. Appl Soil Ecol 44 (3), 205-212.
[50] McCauley, A., Jones, C. and Jacobsen, C. D., 2009. Soil pH and organic matter. Nutrient management modules 8, #4449-8. Montana State University Extension Service, Bozeman, Montana, pp. 1-12.
[51] Morgan, R., 2013. Soil, Heavy Metals and Human Health. In Brevik, E. C., Burgess, L. C., 2013. Soils and Human Health. Boca Raton. FL: CRC Press, pp. 59-80.
[52] Obata, H. and Omebayashi, M., 1997. Effects of cadmium on mineral nutrient concentrations in plants differing in tolerance for cadmium. Journal of Plant Nutrition 20, 97-105.
[53] Pan, J. J. 2004. Land resources survey and evaluation. Beijing: China Agriculture Press, pp. 27.
[54] Redondo-Gomez, S., Cantos, M., Mateos-Naranjo, E., Figueroa, M. and Troncoso, A., 2009. Heavy metals and trace element concentrations in intertidal soils of four estuaries of SW Iberian Peninsula. Soil & Sediment Contamin 18, 320-327.
[55] Rodrigues, S. M., Cruz, N., Coelho, C., Henriques, B., Carvalho, L., Duarte, A. C., Pereira, E. and Romkens, P. F., 2013. Risk assessment for Cd, Cu, Pb, and Zn in urban soils: chemical availability as the central concept. Environ Pollut 183, 234-242.
[56] Sanita, L. T. and Gabbrielli, R., 1999. Response to cadmium n higher plants. Environmental and Experimental Botany 41, 105-130.
[57] Sebastian, A. and Prasad, M. N. V., 2015. Trace element management in rice. Agronomy 5, 374-404. doi: 10.3390/agronomy5030374.
[58] Sherene, T., 2010. Mobility and transport of heavy metals in polluted soil environment. Biological Forum-An International Journal 2 (2), 112-121.
[59] Smith, J. L. and Doran, J. W., 1996. Measurement and use of pH and Electrical Conductivity for Soil Quality Analysis. In Methods for Assessing Soil Quality; Doran JW and Jones AJ, eds. SSSA Spec. Publ. 49, Sci. Soc. Amer: Madison, Wisconsin, 169-185.
[60] Sohlenius, G. and Öborn, I., 2004. Geochemistry and partitioning of trace metals in acid sulphate soils in Sweden and Finland before and after sulphide oxidation. Geoderma 122, 167-175.
[61] Soil Fertility Monitoring Tools. htm. 2014. Department of primary and industries. The state of Victoria. http://www.depi.vic.gov.au/...and...victorian...monitoring-tools/soil-fertility.
[62] Soil Survey Division Staff. 1993. Soil Survey Manual. USDA Handbook 18, U. S. Government Printing Office, Washington, DC.
[63] Soltani, S. M., Hanafi, M. M., Wahid, S. A. and Kharidah, S. M. S., 2015. Zinc fractionation of tropical paddy soils and their relationships with selected soil properties. Chemical Speciation & Bioavailability, Vol. 27 No.2, 53-61. http://dx.doi.org/10.1080/09542299.2015.1023091.
[64] SujathaDantu. 2010. Geochemical patterns in soils in and around Siddipet, Medak District, Andhra Pradesh, India. Environmental Monitoring and Assessment 170, 681-701.
[65] Tu, C., He, T., Liu, C., Lu, X. and Lang, Y., 2011. Accumulation of trace elements in agricultural topsoil under different geological background. Plant and Soil 349, 241-251.
[66] USDA. 2016. United States Department of Agriculture, Soil taxonomy. https://en.wikipedia.org/wiki/USDA-soil-taxonomy#Example-of-classification-of-a-soil-type.
[67] USEPA. 2003. United State Environmental Protection Agency. Ecological soil screening level for aluminum. Interim final. OSWER Directive 9285. Washington DC, 7-60.
[68] USEPA. 2010. United State Environmental Protection Agency; Method 3050B. Acid Digestion of Sediments, Sludges and Soils, http://www.epa.gov/waste/hazard/ test methods/sw846/pdfs/3050b.pdf, accessed June/.
[69] Usman, A. R. A., Kuzyakov, Y. and Stahr, K., 2008. Sorption, desorption and immobilization of heavy metals by artificial soil. MSc. Thesis, University of Hohenhiem, Stuttgart.
[70] Vamerali, T., Bandiea, M. and Mosca, G., 2010. Field crops for phytoremediation of metal-contaminated land. A review. Environ Chem Letter 8, 1-17.
[71] Van Reeuwijk, L. P. 2002. Procedures for soil analysis. Sixth edition. International soil reference and information centre. Food and agriculture organization of the United Nations.
[72] Vega, F. A., Covelo, E. F. and Andrade, M. L. 2005. Limiting factors for reforestation of mine spoils from Galicia (Spain). Land Degradation and Development 16, 27-36.
[73] Vega, F. A., Covelo, E. F., Andrade, M. L. and Marcet, P., 2004. Relationships between heavy metals content and soil properties in mine soils. Analytica Chimica Acta 524, 141-150.
[74] Vidal, J., Perez-Sirvent, C., Martinez-Sanchez, M. J., Navarro, M. C., 2004. Origin and behavior of heavy metals in agricultural Calcaric Fluvisols in semiarid conditions. Geoderma 121, 257-270.
[75] Virtanen, S., Simojoki, A., Rita, H., Toivonen, J., Hartikainen, H. and Yli-Halla, M., 2014. A multi-scale comparison of dissolved Al, Fe and S in a boreal acid sulphate soil. Sciences of the Total Environment 499, 336-348.
[76] Wahsha, M., Bini, C., Fontana, S., Wahsha, A. and Zilioli, D. 2012. Toxicity assessment of contaminated soils from a mining area in Northeast Italy by using lipid peroxidation assay. J. Geochem. Explor 113, 112-117.
[77] Wangstrand, H., Eriksson, J., Oborn, I., 2007. Cadmium concentration in winter wheat as affected by nitrogen fertilization. European Journal of Agronomy 26, 209-214.
[78] Watson, M. E. and Brown, J. R., 2014. pH and lime requirement in soil analysis and methods. University of Minnesota. http://ral.cfans.umn.edu/soil-analysis-and methods/.
[79] WHO, 1996. World Health organization Guidelines for Drinking water quality. 2nd Ed., Vol.2, Health Criteria and Supporting Information, WHO, Geneva.
[80] Yang, M. G., Lin, X. Y. and Yang, X. E., 1998. Impact of Cd on growth and nutrient accumulation of different plant specied. Chinese Journal of Applied Ecology 19, 89-94.
[81] Zadrozny, P. and Nicia, P., 2009. Heavy metals in the peat soils of the Konecki County. Ecological Chemistry and Engineering Vol. 16 No. 9.
[82] Zayed, A. M. and Terry, N., 2003. Chromium in the environment: factors affecting biological remediation. Plant Soil 249, 139-156.
[83] Zhang, F. R. 2002. Soil geography. Beijing: China Agriculture Press, 17.
[84] Zhao, K. L., Liu, X. M., Xu, J. M. and Selim, H. M. 2010. Heavy metal contaminations in a soil-system: identification of spatial dependence in relation to soil properties of paddy fields. Journal of Hazardous Materials 181, 778-787.
Cite This Article
Plain Text BibTeX RIS

  • APA Style

    Kyi Pyar Zin, L. H. Lim, J. M. R. Sarath Bandara, H. M. Thippeswamy. (2017). Heavy Metals in Paddy Soils of Brunei Darussalam and Their Relationship with Selected Soil Properties. International Journal of Environmental Monitoring and Analysis, 5(3), 64-72. https://doi.org/10.11648/j.ijema.20170503.11

    Copy | Download

    ACS Style

    Kyi Pyar Zin; L. H. Lim; J. M. R. Sarath Bandara; H. M. Thippeswamy. Heavy Metals in Paddy Soils of Brunei Darussalam and Their Relationship with Selected Soil Properties. Int. J. Environ. Monit. Anal. 2017, 5(3), 64-72. doi: 10.11648/j.ijema.20170503.11

    Copy | Download

    AMA Style

    Kyi Pyar Zin, L. H. Lim, J. M. R. Sarath Bandara, H. M. Thippeswamy. Heavy Metals in Paddy Soils of Brunei Darussalam and Their Relationship with Selected Soil Properties. Int J Environ Monit Anal. 2017;5(3):64-72. doi: 10.11648/j.ijema.20170503.11

    Copy | Download 

  • @article{10.11648/j.ijema.20170503.11,
  author = {Kyi Pyar Zin and L. H. Lim and J. M. R. Sarath Bandara and H. M. Thippeswamy},
  title = {Heavy Metals in Paddy Soils of Brunei Darussalam and Their Relationship with Selected Soil Properties},
  journal = {International Journal of Environmental Monitoring and Analysis},
  volume = {5},
  number = {3},
  pages = {64-72},
  doi = {10.11648/j.ijema.20170503.11},
  url = {https://doi.org/10.11648/j.ijema.20170503.11},
  eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijema.20170503.11},
  abstract = {In Brunei Darussalam, available information of heavy metals in agricultural soils is sparse and hence a baseline study was carried out on soils in rice growing areas. In this study, trace elements as well as common soil characteristics were determined from twenty six of major rice fields such as Wasan, Limau Manis, Selapon and Lot Senkuang. Al, Fe, Mn and Cd were high in these areas however; Cu, Zn, Cr, Co, Ni and Pb were below safety limit of soil while Mn and Cd were above the permissible limit according to the WHO/CCME/European Union guidelines. The variations in metal concentrations in these samples are highly correlated to the acidic condition, organic matter and CEC of the paddy soils. The distributions of Al, Fe, Cu, Mn, Cd, Cr, Co, Pb were high at low pH. Cu, Zn, Cd, Ni and Pb showed positive correlation with organic matter while the quantities of Al, Fe, Mn, Cr and Co were negatively correlated. Correlation analyses showed that the Cd, Zn and Ni were associated with CEC while most of the metals were related to Al and Fe. The soils of the studied areas are extremely acidic with pH 3.0-4.6, and low in cations, CEC and available P, while having a high OM content. Low content of P was due to high amount of Al and Fe in these areas.},
 year = {2017}
}

    Copy | Download 

  • TY  - JOUR
T1  - Heavy Metals in Paddy Soils of Brunei Darussalam and Their Relationship with Selected Soil Properties
AU  - Kyi Pyar Zin
AU  - L. H. Lim
AU  - J. M. R. Sarath Bandara
AU  - H. M. Thippeswamy
Y1  - 2017/04/13
PY  - 2017
N1  - https://doi.org/10.11648/j.ijema.20170503.11
DO  - 10.11648/j.ijema.20170503.11
T2  - International Journal of Environmental Monitoring and Analysis
JF  - International Journal of Environmental Monitoring and Analysis
JO  - International Journal of Environmental Monitoring and Analysis
SP  - 64
EP  - 72
PB  - Science Publishing Group
SN  - 2328-7667
UR  - https://doi.org/10.11648/j.ijema.20170503.11
AB  - In Brunei Darussalam, available information of heavy metals in agricultural soils is sparse and hence a baseline study was carried out on soils in rice growing areas. In this study, trace elements as well as common soil characteristics were determined from twenty six of major rice fields such as Wasan, Limau Manis, Selapon and Lot Senkuang. Al, Fe, Mn and Cd were high in these areas however; Cu, Zn, Cr, Co, Ni and Pb were below safety limit of soil while Mn and Cd were above the permissible limit according to the WHO/CCME/European Union guidelines. The variations in metal concentrations in these samples are highly correlated to the acidic condition, organic matter and CEC of the paddy soils. The distributions of Al, Fe, Cu, Mn, Cd, Cr, Co, Pb were high at low pH. Cu, Zn, Cd, Ni and Pb showed positive correlation with organic matter while the quantities of Al, Fe, Mn, Cr and Co were negatively correlated. Correlation analyses showed that the Cd, Zn and Ni were associated with CEC while most of the metals were related to Al and Fe. The soils of the studied areas are extremely acidic with pH 3.0-4.6, and low in cations, CEC and available P, while having a high OM content. Low content of P was due to high amount of Al and Fe in these areas.
VL  - 5
IS  - 3
ER  -

    Copy | Download

Author Information

  • Kyi Pyar Zin

    Chemical Sciences, Faculty of Science, Universiti Brunei Darussalam, Brunei Darussalam; A-1, Irrigation Compound, 8? Mile, Republic of the Union of Myanmar

  • L. H. Lim

    Chemical Sciences, Faculty of Science, Universiti Brunei Darussalam, Brunei Darussalam

  • J. M. R. Sarath Bandara

    Environmental and Life Sciences, Faculty of Science, Universiti Brunei Darussalam, Brunei Darussalam

  • H. M. Thippeswamy

    Soil Science and Plant Nutrition Unit, Crop Industry Division, Department of Agriculture and Agrifood, Ministry of Primary Resources and Tourism, Brunei Darussalam

Download PDF
  • Sections

About Us

Science Publishing Group (SciencePG) is an Open Access publisher, with more than 300 online, peer-reviewed journals covering a wide range of academic disciplines.

Learn More About SciencePG

Products

Information

Important Link

Copyright © 2012 -- 2024 Science Publishing Group – All rights reserved.