BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY

Güllü Kırat; Cemal Bolucek

Araştırma Makalesi

BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY

Yıl 2018, Cilt: 13 Sayı: 1, 53 - 63, 19.01.2018

Öz

Biogeochemical
studies have been carried out on Prunus armeniaca L. plant grown in and around
Pb-Zn deposits in Gorgu village and on the soil samples grown on this plant.
Chemical analyzes of plant and soil samples taken in the study area were carried
out in the ACME analytical laboratory in Canada by ICP-MS method. The average
Pb concentration of branch, leaf, fruit and soil of Prunus Armeniaca L. (P.
Armeniaca) plant was (mg/kg), respectively; 15.1, 13.7, 3.5 and 1495.5, and Zn
concentration, respectively (mg/kg); 29, 44.3, 36.4 and 1831.7. The average BAC
(Bioaccumulation Coefficient) values calculated for the Pb element of the
P. Armeniaca plant were BAC (branch/soil):0.01, BAC (leaf/soil):0.01 and BAC (fruit/soil):0.004
and the average BAC values calculated for the Zn element, BAC (branch/soil):0.04,
BAC (leaf/soil):0.05 and BAC (fruit/soil):0.07. For this reason, this plant is a medium accumulator plant in
the locations determined for Cu, Mo and Zn elements.

Anahtar Kelimeler

Accumulator Plant, BAC (Bioaccumulation Coefficient) Prunus armeniaca L, Pb-Zn, Yeşilyurt-Görgü

Kaynakça

1. Adriano, D.C., Wenzel, W.W., Vangronsveld, J., and Bolan, N.S., (2004). Role of Assisted Natural Remediation in Environmental Cleanup, Geoderma. J., Vol. 122, no. 2-4, 121–142.
2. Raicevic, S., Kaludjerovic-Radoicic, T., and Zouboulis, A.I., (2005). In Situ Stabilization of Toxic Metals in Polluted Soils Using Phosphates: Theoretical Prediction and Experimental Verification, J. Hazard, Mat. J., vol. 117, no. 1, pp, 41–53.
3. Cheraghi, M., Lorestani, B., Khorasani, N., Yousefi, N., and Karami, M., (2011). Findings on the Phytoextraction and Phytostabilization of Soils Contaminated with Heavy Metals, Biol. Trace Elem. Res. 144:1133-1141.
4. Nazır, R., Khan, M., Masab, M., Rehman, H.U., Rauf, N.U., Shahab, S., Ameer, N., Sajed, M., Ullah, M., Rafeeq, M., and Shaheen, Z., (2015). Accumulation of Heavy Metals (Ni, Cu, Cd, Cr, Pb, Zn, Fe) in the Soil, Water and Plants and Analysis of Physico-chemical Parameters of Soil and Water Collected from Tanda Dam Kohat, J. Pharm. Sci. & Res. Vol. 7(3), 89-97.
5. Hall, J., (2002). Cellular Mechanisms for Heavy Metal Detoxification and Tolerance, J. Exp. Bot., 53, 1-11.
6. Mehes-Smith, M., Nkongolo, K., and Cholewa, E., (2013). Coping Mechanisms of Plants to Metal Contaminated Soil, Environmental Change and Sustainability. http://dx.doi.org/10.5772/55124.
7. Akın, E.V., Karabulut, I., and Topçu, A., (2008). Some Compositional Properties of Main Malatya Apricot (Prunus armeniaca L.) varieties, Food Chemistry, 107, 939-948.
8. https://en.wikipedia.org/wiki/Apricot.
9. http://tr.wikipedia.org/wiki/ Kayısı.
10. Ozgul, N., (1976). Some Geological Aspects of the Taunts Orogenic Belt, Bulletin of the Geological Society of Turkey, v. 19, 65 – 78.
11. Onal, M., Tuzcu, N. and Helvacı, C., 1990, Geological Setting, Mineralogy an Origin of the Cafana (Malatya) Zn-Pb Sulfide and Carbonate Deposit, E Anatolia, Turkey, in: Int. Earth Sci. Congress on Aegean Regions, Proceedings, ed: M.Y. Savasçın and A.H. Eronat, Izmir, D.E. University, v. 1, 52-58.
12. Cengiz, R., Yılmaz, H., and Türkyılmaz, B., (1991). In the Near Malatya–Yeşilyurt–Cafana (Görgü) Interim Report License Areas Number ÖİR:671 and ÖİR:1714 Belonging Çinkur. Mineral Research & Exploration General Directorate, Ankara.
13. Sagiroglu, A., (1988). Cafana (Gorgu) Malatya Carbonated Pb–Zn Deposit. C.Ü. Faculty of Engineering Journal, Series A Geosciences, C. 5(1), 3-13.
14. Ceyhan, N., (2003). Lead Isotope Geochemistry of Pb-Zn Deposits from Eastern Taurides, Turkey. Middle East Technical University, Msc Thesis, pp., 105.
15. Reichman, S.M., Asher, C.J., Mulligan, D.R., and Menzies, N.W., (2001). Seedling Responses of Three Australian Tree Species to Toxic Concentrations of Zinc in Solution Culture, Plant and Soil, 235, 151-158.
16. Ernst, WHO., (1974). Schwermetallvegetation der Erde. Gustav Fischer, Stuttgart.
17. Ernst, WHO., (1982). Schwermetallpflanzen. In: Kinzel H (ed) Pflanzen€okologie und Mineral-Stoffwechsel. Ulmer, Stuttgart, 472–506.
18. Bothe, H., (2011). Plants in Heavy Metal Soils. Chapter 2, 35-57.
19. Hassan, Z., Anwar, Z. Khattak, K.U., Islam, M., Khan, R.U., Khattak, J.Z.K.; et al., (2002). Civic Pollution and Its Effect on Water Quality of River Toi at District Kohat, NWFP, Research Journal of Environmental and Earth Sciences, Volume: 4, p.5.

Yıl 2018, Cilt: 13 Sayı: 1, 53 - 63, 19.01.2018

Güllü Kırat Cemal Bolucek

Öz

Kaynakça

1. Adriano, D.C., Wenzel, W.W., Vangronsveld, J., and Bolan, N.S., (2004). Role of Assisted Natural Remediation in Environmental Cleanup, Geoderma. J., Vol. 122, no. 2-4, 121–142.
2. Raicevic, S., Kaludjerovic-Radoicic, T., and Zouboulis, A.I., (2005). In Situ Stabilization of Toxic Metals in Polluted Soils Using Phosphates: Theoretical Prediction and Experimental Verification, J. Hazard, Mat. J., vol. 117, no. 1, pp, 41–53.
3. Cheraghi, M., Lorestani, B., Khorasani, N., Yousefi, N., and Karami, M., (2011). Findings on the Phytoextraction and Phytostabilization of Soils Contaminated with Heavy Metals, Biol. Trace Elem. Res. 144:1133-1141.
4. Nazır, R., Khan, M., Masab, M., Rehman, H.U., Rauf, N.U., Shahab, S., Ameer, N., Sajed, M., Ullah, M., Rafeeq, M., and Shaheen, Z., (2015). Accumulation of Heavy Metals (Ni, Cu, Cd, Cr, Pb, Zn, Fe) in the Soil, Water and Plants and Analysis of Physico-chemical Parameters of Soil and Water Collected from Tanda Dam Kohat, J. Pharm. Sci. & Res. Vol. 7(3), 89-97.
5. Hall, J., (2002). Cellular Mechanisms for Heavy Metal Detoxification and Tolerance, J. Exp. Bot., 53, 1-11.
6. Mehes-Smith, M., Nkongolo, K., and Cholewa, E., (2013). Coping Mechanisms of Plants to Metal Contaminated Soil, Environmental Change and Sustainability. http://dx.doi.org/10.5772/55124.
7. Akın, E.V., Karabulut, I., and Topçu, A., (2008). Some Compositional Properties of Main Malatya Apricot (Prunus armeniaca L.) varieties, Food Chemistry, 107, 939-948.
8. https://en.wikipedia.org/wiki/Apricot.
9. http://tr.wikipedia.org/wiki/ Kayısı.
10. Ozgul, N., (1976). Some Geological Aspects of the Taunts Orogenic Belt, Bulletin of the Geological Society of Turkey, v. 19, 65 – 78.
11. Onal, M., Tuzcu, N. and Helvacı, C., 1990, Geological Setting, Mineralogy an Origin of the Cafana (Malatya) Zn-Pb Sulfide and Carbonate Deposit, E Anatolia, Turkey, in: Int. Earth Sci. Congress on Aegean Regions, Proceedings, ed: M.Y. Savasçın and A.H. Eronat, Izmir, D.E. University, v. 1, 52-58.
12. Cengiz, R., Yılmaz, H., and Türkyılmaz, B., (1991). In the Near Malatya–Yeşilyurt–Cafana (Görgü) Interim Report License Areas Number ÖİR:671 and ÖİR:1714 Belonging Çinkur. Mineral Research & Exploration General Directorate, Ankara.
13. Sagiroglu, A., (1988). Cafana (Gorgu) Malatya Carbonated Pb–Zn Deposit. C.Ü. Faculty of Engineering Journal, Series A Geosciences, C. 5(1), 3-13.
14. Ceyhan, N., (2003). Lead Isotope Geochemistry of Pb-Zn Deposits from Eastern Taurides, Turkey. Middle East Technical University, Msc Thesis, pp., 105.
15. Reichman, S.M., Asher, C.J., Mulligan, D.R., and Menzies, N.W., (2001). Seedling Responses of Three Australian Tree Species to Toxic Concentrations of Zinc in Solution Culture, Plant and Soil, 235, 151-158.
16. Ernst, WHO., (1974). Schwermetallvegetation der Erde. Gustav Fischer, Stuttgart.
17. Ernst, WHO., (1982). Schwermetallpflanzen. In: Kinzel H (ed) Pflanzen€okologie und Mineral-Stoffwechsel. Ulmer, Stuttgart, 472–506.
18. Bothe, H., (2011). Plants in Heavy Metal Soils. Chapter 2, 35-57.
19. Hassan, Z., Anwar, Z. Khattak, K.U., Islam, M., Khan, R.U., Khattak, J.Z.K.; et al., (2002). Civic Pollution and Its Effect on Water Quality of River Toi at District Kohat, NWFP, Research Journal of Environmental and Earth Sciences, Volume: 4, p.5.

Toplam 19 adet kaynakça vardır.

Ayrıntılar

Konular	Mühendislik
Bölüm	Makaleler
Yazarlar	Güllü Kırat 0000-0002-1167-0574 Cemal Bolucek Bu kişi benim
Yayımlanma Tarihi	19 Ocak 2018
Yayımlandığı Sayı	Yıl 2018 Cilt: 13 Sayı: 1

Kaynak Göster

APA	Kırat, G., & Bolucek, C. (2018). BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY. Engineering Sciences, 13(1), 53-63.
AMA	Kırat G, Bolucek C. BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY. Engineering Sciences. Ocak 2018;13(1):53-63.
Chicago	Kırat, Güllü, ve Cemal Bolucek. “BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY”. Engineering Sciences 13, sy. 1 (Ocak 2018): 53-63.
EndNote	Kırat G, Bolucek C (01 Ocak 2018) BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY. Engineering Sciences 13 1 53–63.
IEEE	G. Kırat ve C. Bolucek, “BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY”, Engineering Sciences, c. 13, sy. 1, ss. 53–63, 2018.
ISNAD	Kırat, Güllü - Bolucek, Cemal. “BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY”. Engineering Sciences 13/1 (Ocak 2018), 53-63.
JAMA	Kırat G, Bolucek C. BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY. Engineering Sciences. 2018;13:53–63.
MLA	Kırat, Güllü ve Cemal Bolucek. “BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY”. Engineering Sciences, c. 13, sy. 1, 2018, ss. 53-63.
Vancouver	Kırat G, Bolucek C. BIOACCUMULATOR CHARACTERISTICS FOR Pb-Zn OF PRUNUS ARMENIACA L. PLANT (YEŞİLYURT-GÖRGÜ), TURKEY. Engineering Sciences. 2018;13(1):53-6.