Year 2016,
Volume: 29 Issue: 4, 963 - 970, 20.12.2016
Güllü Kırat
,
Nasuh Aydın
References
- WHO, World Health Organization. Environmental Health Criteria 204: Boron. Geneva, Switzerland: World Health Organization (as cited in U.S. EPA, 2004), 1998.
- Shorrocks, V., The occurrence and correction of boron deficiency. Plant Soil 193, 121-148, 1997.
- Camacho-Cristóbal, J.J., Rexach, J., González-Fontes, A., Boron in plants: deficiency and toxicity. Departamento de Fisiología, Anatomía y Biología Celular, Facultad de Ciencias Experimentales, Universidad Pablo de Olavide, E-41013 Sevilla, Spain, 2007.
- Rámila, C.D.P., Eduardo D. Leiva, Carlos A. Bonilla, Pablo A. Pastén, Gonzalo E. Pizarro, Boron accumulation in Puccinellia frigida, an extremely tolerant and promising species for boron phytoremediation. Journal of Geochemical Exploration, 150, 25–34, 2015.
- Singh, R.K., Sharma, R.P., Zinc and boron accumulation in barley grains and it’s relation with soil. International Journal of Green and Herbal Chemistry. 2012, Vol.1.No.1, 21-25, 2012.
- Arı Baykal, Ş., Öncel, I., Changes of Soluble Phenolic and Soluble Protein Amounts on the Tolerance of Boron Toxicity in Wheat Seedlings. Cumhuriyet Unıversity. Arts and Sciences Faculty, Science Journal, Volume 27, Issue 1. 13-25, 2006.
- Nable, R. O. Bañuelos, G. S. Paull, J. G., Boron Toxicity. Boron in soils and plants: Plant and Soil. 198, 181-198, 1997.
- Sarma, H., Metal Hyperaccumulation in plants: A Review Focusing on Phytoremediation Technology. Journal of Environmental Science and Technology, 4 (2): 118-138, 2011.
- Mench, M., Lepp, N., Bert, V., Schwitzguébel, J.-P., Gawronski, S.W., Schöder, P., Vangronsveld, J., Successes and limitations of phytotechnologies at field scale: outcomes, assessment and outlook from COST action 859. J. Soils Sediments 10, 1039-1070, 2010.
- Rafati, M., Khorasani, N., Moattar, F., Shirvany, A., Moraghebi, F. and Hosseinzadeh, S., Phytoremediation Potential of Populus Alba and Morus alba for Cadmium, Chromuim and Nickel Absorption from Polluted Soil. Int. J. Environ. Res., 5(4):961-970, 2011.
- Karaömerlioğlu, B., Medicago Sativa L. and Vicia Sativa L. Bitkileri Kullanılarak Topraktan Bor Gideriminin Araştırılması. Çukurova Unıversity. Institute of Science, Master of Science Thesis. 77p, 2011.
- Shen, Z. G., and Liu. Y. L., Progress in the study on plants that hyperaccumulate heavy metal. Plant Physiol Commun. 49:643–668, 1998.
- McGrath, S. P., and Zhao. F. J., Phytoextraction of metals and metalloids from contaminated soils. Curr. Opin. Biotechnol. 14, 277–282, 2003.
- Yanqun, Z., Yuan, L., Jianjun, C., Haiyan, C., Li, Q., Schvartz, C., “Hyperaccumulation of Pb, Zn and Cd in herbaceous grown on lead-zinc mining area in Yunnan, China,” Environ. Int. J., vol. 31, no. 5, pp, 755– 762, 2005.
- Xiaoha L., Yuntao Z., Khan S., Gang D., Aikui C., Li L., Lei Z., Zhonghan L., and Xuecan., Accumulation of Pb, Cu and Zn in native plants growing on contaminated sites and their potential accumulation capacity in Heqing, Yunnan journal of environmental science, 20, pp 1469-1474, 2008.
- Brooks, R. R., Lee, J. R.R. Reeves, R.D., Jaffre, T., Detection of nickeliferous rocks by analysis of herbarium specimens of indicator plants. Journal of Geochemical Exploration, 7, 49-77, 1977.
- Ma, L.Q., Komar, K.M., Tu, C., Zhang, W., Caı, Y. and Kennelley, E.D., A fern that hyperaccumulates arsenic. Nature, 409, 579, 2001.
- Sağıroğlu, A., Contact metasomatism and ore deposition of thethe Lead-Zinc deposits of Akdağmadeni, Yozgat, Turkey (PhD thesis), Londra University. England (unpublished), 1982.
- Çolakoğlu, A., and Genç, Y., Macro-Micro Textures and Genetic Evoluation of Lead-Zinc Deposits of Akdağmadeni (Yozgat) Region, Geological Bulletin of Turkey, 44, 1, 2001.
- http://acmelab.com/
- Hajara, E.W.I., Sulaimanb, A.Z.B. Sakinah, A.M.M., Assessment of Heavy Metals Tolerance in Leaves, Stems and Flowers of Stevia rebaudiana Plant. Procedia Environmental Sciences, 20, 386 – 393, 2014.
- Reichman, S.M., Asher, C.J., Mulligan, D.R., Menzies, N.W., Seedling responses of three Australian tree species to toxic concentrations of zinc in solution culture. Plant and Soil, 235, 151-158, 2001.
- Şasmaz, A., Translocation and accumulation of boron in roots and shoots of plants grown in soils of low B concentration in Turkey’s Keban Pb-Zn mining area. International Journal of Phytoremediation, 10, 302–310, 2008.
- Yoon, J., Cao, X., Zhou, Q. and Ma L.Q., Accumulation of Pb, Cu and Zn in native plants growing on a contaminated Flarida site. Science of the Total Environment, 368 456-464, 2006.
- Soda, S., Hamada, T., Yamoaka, Y., Ike, M., Nakazato, H., Saeki, Y., Kasamatsu, T., Sakurai Y., Constructed wetlands for advanced treatment of wastewater with a complex matrix from a metal-processing plant: Bioconcentration and translocation factors of various metals in Acorus gramineus and Cyperus alternifolius. Ecological engineering. 39: 63-70, 2012.
- Selvaraj, K., Sevugaperumal R., Ramasubramanian, V., Phytoremedıatıon Of Arsenıc Chlorıde By Indıan Mustard (Brassıca Juncea). Indian Journal of Fundamental and Applied Life Sciences, Vol. 3 (1) January-March, pp.184-191, 2013.
- Madera-Parra, C. A., Peña-Salamanca, E. J., Peña, M. R., Rousseau D. P.L., Lens, P. N.L., Phytoremediation of landfill leachate with Colocasia esculenta, Gynerum sagittatum and Heliconia psittacorum in constructed wetlands. International Journal of Phytoremediation. 1-31, 2013.
- Zu, Y. Q., L. Yuan, C. Jianjun, C. Haiyan, Q. Li, and C. Schvartz., Hyperaccumulation of Pb, Zn and Cd in herbaceous grown on lead-zinc mining area in Yunnn, China. Environ. Int. 31:755–762, 2005.
- Papastergios, G., Georgakopoulos, A., Fernandez - Turiel, J.L., Gimeno, D., Filippidis, A., Kassoli-Fournaraki, A., and Grigoriadou, A., Heavy Metals and Toxic Trace elements contents in selected areas of the Kavala Prefecture, Northern Greece, Bulletin of the Geo logical Society of Greece vol. XXXVI, 2004, Proceedings of the 10th International Congress, Thessaloniki, April 2004,. 1, 263-272, 2004.
- Lorestani, B., Cheraghi, M., Yousefi, N., Phytoremediation Potential of Native Plants Growing on a Heavy Metals Contaminated Soil of Copper mine in Iran. World Academy of Science, Engineering and Technology, 53, 2011.
- Miçillioğlu, S., Researchıng Of Clarıfıcatıonalbılıty Of Waters Wıth Hıgh Concantratıon Of Boron By Usıng Lactuca Satıva. Çukurova Unıversıty Department Of Envıronmental Engıneerıng Instıtute Of Natural And Applıed Scıence, MSc Thesıs, 69p. Adana, 2010.
- Zhao, F.J., Lombi, E., McGrth, S.P., Assessing the potential for zinc and cadmium phytoremediation with the hyperaccumulator Thlaspi caerulescens. Plant and Soil, 249, 37-43, 2003.
- Baker, A.J.M., and Brooks, R.R., Terrestrial higher plants which hyperaccumulate metallic elements - a review of their distribution, ecology and phytochemistry, Biorecovery, 1, pp 81-126, 1989.
- Stıngu, A., Stanescu, Volf, I., Popa, V.I., Hyperaccumulatıon Of Cadmıum In Maıze Plant. Cellulose Chem. Technol., 45 (3-4), 287-290, 2011.
- Mellem, J., Bijnath, H., and Odhav, B., Bioaccumulation of Cr, Hg, As, Pb, Cu and Ni with the ability for hyperaccumulation by Amaranthus dublis. African Journal of Agricultural Research, 7(4), 591-596, 2012.
Phytoremediation with Plants for Soils Polluted by Boron at Akdagmadeni Pb-Zn Mining District and Surroundings
Year 2016,
Volume: 29 Issue: 4, 963 - 970, 20.12.2016
Güllü Kırat
,
Nasuh Aydın
Abstract
The amount of elements in plants is important for biogeochemical explorations. In this study 28 plant species and soil samples were collected from boron deposit area in Akdağmadeni. Boron is determined in plants and soil samples. Additionally, statistical relations were established between the boron values of plant and soil samples. Metal pollution has become one of the most serious environmental problems. Phytoremediation utilizes plants to uptake contaminants and can potentially be used to remediate metal-contaminated sites. The present study investigates boron uptake from soil by different organs of Astragalus pycnocephalus Fischer and Verbascum euphraticum L. The concentration of this metal was measured in the roots, shoots, leaves, and the soil. Assay results show that the highest accumulation of boron was found in the roots. In addition, the determination of a enrichement coefficient and a translocation factor showed that both plant types were suitable for phytoremediation of Boron.
References
- WHO, World Health Organization. Environmental Health Criteria 204: Boron. Geneva, Switzerland: World Health Organization (as cited in U.S. EPA, 2004), 1998.
- Shorrocks, V., The occurrence and correction of boron deficiency. Plant Soil 193, 121-148, 1997.
- Camacho-Cristóbal, J.J., Rexach, J., González-Fontes, A., Boron in plants: deficiency and toxicity. Departamento de Fisiología, Anatomía y Biología Celular, Facultad de Ciencias Experimentales, Universidad Pablo de Olavide, E-41013 Sevilla, Spain, 2007.
- Rámila, C.D.P., Eduardo D. Leiva, Carlos A. Bonilla, Pablo A. Pastén, Gonzalo E. Pizarro, Boron accumulation in Puccinellia frigida, an extremely tolerant and promising species for boron phytoremediation. Journal of Geochemical Exploration, 150, 25–34, 2015.
- Singh, R.K., Sharma, R.P., Zinc and boron accumulation in barley grains and it’s relation with soil. International Journal of Green and Herbal Chemistry. 2012, Vol.1.No.1, 21-25, 2012.
- Arı Baykal, Ş., Öncel, I., Changes of Soluble Phenolic and Soluble Protein Amounts on the Tolerance of Boron Toxicity in Wheat Seedlings. Cumhuriyet Unıversity. Arts and Sciences Faculty, Science Journal, Volume 27, Issue 1. 13-25, 2006.
- Nable, R. O. Bañuelos, G. S. Paull, J. G., Boron Toxicity. Boron in soils and plants: Plant and Soil. 198, 181-198, 1997.
- Sarma, H., Metal Hyperaccumulation in plants: A Review Focusing on Phytoremediation Technology. Journal of Environmental Science and Technology, 4 (2): 118-138, 2011.
- Mench, M., Lepp, N., Bert, V., Schwitzguébel, J.-P., Gawronski, S.W., Schöder, P., Vangronsveld, J., Successes and limitations of phytotechnologies at field scale: outcomes, assessment and outlook from COST action 859. J. Soils Sediments 10, 1039-1070, 2010.
- Rafati, M., Khorasani, N., Moattar, F., Shirvany, A., Moraghebi, F. and Hosseinzadeh, S., Phytoremediation Potential of Populus Alba and Morus alba for Cadmium, Chromuim and Nickel Absorption from Polluted Soil. Int. J. Environ. Res., 5(4):961-970, 2011.
- Karaömerlioğlu, B., Medicago Sativa L. and Vicia Sativa L. Bitkileri Kullanılarak Topraktan Bor Gideriminin Araştırılması. Çukurova Unıversity. Institute of Science, Master of Science Thesis. 77p, 2011.
- Shen, Z. G., and Liu. Y. L., Progress in the study on plants that hyperaccumulate heavy metal. Plant Physiol Commun. 49:643–668, 1998.
- McGrath, S. P., and Zhao. F. J., Phytoextraction of metals and metalloids from contaminated soils. Curr. Opin. Biotechnol. 14, 277–282, 2003.
- Yanqun, Z., Yuan, L., Jianjun, C., Haiyan, C., Li, Q., Schvartz, C., “Hyperaccumulation of Pb, Zn and Cd in herbaceous grown on lead-zinc mining area in Yunnan, China,” Environ. Int. J., vol. 31, no. 5, pp, 755– 762, 2005.
- Xiaoha L., Yuntao Z., Khan S., Gang D., Aikui C., Li L., Lei Z., Zhonghan L., and Xuecan., Accumulation of Pb, Cu and Zn in native plants growing on contaminated sites and their potential accumulation capacity in Heqing, Yunnan journal of environmental science, 20, pp 1469-1474, 2008.
- Brooks, R. R., Lee, J. R.R. Reeves, R.D., Jaffre, T., Detection of nickeliferous rocks by analysis of herbarium specimens of indicator plants. Journal of Geochemical Exploration, 7, 49-77, 1977.
- Ma, L.Q., Komar, K.M., Tu, C., Zhang, W., Caı, Y. and Kennelley, E.D., A fern that hyperaccumulates arsenic. Nature, 409, 579, 2001.
- Sağıroğlu, A., Contact metasomatism and ore deposition of thethe Lead-Zinc deposits of Akdağmadeni, Yozgat, Turkey (PhD thesis), Londra University. England (unpublished), 1982.
- Çolakoğlu, A., and Genç, Y., Macro-Micro Textures and Genetic Evoluation of Lead-Zinc Deposits of Akdağmadeni (Yozgat) Region, Geological Bulletin of Turkey, 44, 1, 2001.
- http://acmelab.com/
- Hajara, E.W.I., Sulaimanb, A.Z.B. Sakinah, A.M.M., Assessment of Heavy Metals Tolerance in Leaves, Stems and Flowers of Stevia rebaudiana Plant. Procedia Environmental Sciences, 20, 386 – 393, 2014.
- Reichman, S.M., Asher, C.J., Mulligan, D.R., Menzies, N.W., Seedling responses of three Australian tree species to toxic concentrations of zinc in solution culture. Plant and Soil, 235, 151-158, 2001.
- Şasmaz, A., Translocation and accumulation of boron in roots and shoots of plants grown in soils of low B concentration in Turkey’s Keban Pb-Zn mining area. International Journal of Phytoremediation, 10, 302–310, 2008.
- Yoon, J., Cao, X., Zhou, Q. and Ma L.Q., Accumulation of Pb, Cu and Zn in native plants growing on a contaminated Flarida site. Science of the Total Environment, 368 456-464, 2006.
- Soda, S., Hamada, T., Yamoaka, Y., Ike, M., Nakazato, H., Saeki, Y., Kasamatsu, T., Sakurai Y., Constructed wetlands for advanced treatment of wastewater with a complex matrix from a metal-processing plant: Bioconcentration and translocation factors of various metals in Acorus gramineus and Cyperus alternifolius. Ecological engineering. 39: 63-70, 2012.
- Selvaraj, K., Sevugaperumal R., Ramasubramanian, V., Phytoremedıatıon Of Arsenıc Chlorıde By Indıan Mustard (Brassıca Juncea). Indian Journal of Fundamental and Applied Life Sciences, Vol. 3 (1) January-March, pp.184-191, 2013.
- Madera-Parra, C. A., Peña-Salamanca, E. J., Peña, M. R., Rousseau D. P.L., Lens, P. N.L., Phytoremediation of landfill leachate with Colocasia esculenta, Gynerum sagittatum and Heliconia psittacorum in constructed wetlands. International Journal of Phytoremediation. 1-31, 2013.
- Zu, Y. Q., L. Yuan, C. Jianjun, C. Haiyan, Q. Li, and C. Schvartz., Hyperaccumulation of Pb, Zn and Cd in herbaceous grown on lead-zinc mining area in Yunnn, China. Environ. Int. 31:755–762, 2005.
- Papastergios, G., Georgakopoulos, A., Fernandez - Turiel, J.L., Gimeno, D., Filippidis, A., Kassoli-Fournaraki, A., and Grigoriadou, A., Heavy Metals and Toxic Trace elements contents in selected areas of the Kavala Prefecture, Northern Greece, Bulletin of the Geo logical Society of Greece vol. XXXVI, 2004, Proceedings of the 10th International Congress, Thessaloniki, April 2004,. 1, 263-272, 2004.
- Lorestani, B., Cheraghi, M., Yousefi, N., Phytoremediation Potential of Native Plants Growing on a Heavy Metals Contaminated Soil of Copper mine in Iran. World Academy of Science, Engineering and Technology, 53, 2011.
- Miçillioğlu, S., Researchıng Of Clarıfıcatıonalbılıty Of Waters Wıth Hıgh Concantratıon Of Boron By Usıng Lactuca Satıva. Çukurova Unıversıty Department Of Envıronmental Engıneerıng Instıtute Of Natural And Applıed Scıence, MSc Thesıs, 69p. Adana, 2010.
- Zhao, F.J., Lombi, E., McGrth, S.P., Assessing the potential for zinc and cadmium phytoremediation with the hyperaccumulator Thlaspi caerulescens. Plant and Soil, 249, 37-43, 2003.
- Baker, A.J.M., and Brooks, R.R., Terrestrial higher plants which hyperaccumulate metallic elements - a review of their distribution, ecology and phytochemistry, Biorecovery, 1, pp 81-126, 1989.
- Stıngu, A., Stanescu, Volf, I., Popa, V.I., Hyperaccumulatıon Of Cadmıum In Maıze Plant. Cellulose Chem. Technol., 45 (3-4), 287-290, 2011.
- Mellem, J., Bijnath, H., and Odhav, B., Bioaccumulation of Cr, Hg, As, Pb, Cu and Ni with the ability for hyperaccumulation by Amaranthus dublis. African Journal of Agricultural Research, 7(4), 591-596, 2012.