TY - JOUR T1 - Boron Adsorption on Lime Soil and Phytoremediation of Lime Soil by Potato Plant (Solanum Tuberosum L.) AU - Korkmaz, Mustafa AU - Özmetin, Cengiz AU - Süzen, Yeliz AU - Mutlu, Atilla PY - 2022 DA - September DO - 10.18466/cbayarfbe.961739 JF - Celal Bayar University Journal of Science JO - CBUJOS PB - Manisa Celal Bayar University WT - DergiPark SN - 1305-130X SP - 239 EP - 247 VL - 18 IS - 3 LA - en AB - Boron adsorption onto lime soil from Balıkesir University campus was studied to evaluate the effects of irrigation water cations (Ca2+, Mg2+, K+ and Na+) and soil clays (kaolinite, montmorillonite, clinoptilolite clays). The concentrations for cations and boron were in the range of 0-1,450 mg/L and 0-700 mg/L, respectively. The experimental maximum boron capacity for cation effect was 0.764 mg/g and this value was seen to obtain at high cation and middle boron concentration (304.49 mg/L) in optimization graph. The maximum experimental boron capacity for clay effect was 1.08 mg/g and this value was obtained from optimization graph at 0.5828 g clinoptilolite, 0.1936 g montmorillonite, 0.5852 g kaolinite amounts. The borated-soil samples were successfully phytoremediated with potato plant and maximum intake of boron by the potato plant was 2,304.8 mg/kg plant. The plant dry weights decreased by increasing soil boron concentration and the potato plants did not grow at 203.56, 303.56, 403.56 mg/kg boron concentrations exhibiting toxic effects for potato plant. The studied soil concentrations for phytoremediation was 3.56, 13.56, 23.56, 33.56, 43.56, 53.56, 103.56, 203.56, 303.56, and 403.56 mg/kg boron. KW - Boron adsorption KW - Lime soil KW - RSM optimization KW - Phytoremediation KW - Potato plant CR - [1] Tariq, M., and Mott, C.J.B. 2007. The significance of boron in plant nutrition and environment-a review. Journal of Agronomy; 6 (1):1-10. CR - [2] Chaudhary, D.R., Shukla, L.M., and Gupta, A. 2005. Boron equilibria in soil-a review. Agricultural Reviews; 26(4):288-294. CR - [3] Başcı, N. 2009. Investigation of Removal of Chromium (VI) Ion from Soil Using Ornamental Plants. Çukurova University, MSc Thesis, Adana City, Turkey (2009). CR - [4] Reynaldo, L., Alleoni, F., Antonio, O., Antonio Decamargo, O. 2000. Boron adsorption in soils from the state of sao Paulo. Pesquisa Agropecuária Brasileira; (35) 2:413-421. CR - [5] Arora, S., Chaha, D.S. 2010. Effect of Soil Properties on Boron Adsorption and Release in Arid and Semi-Arid Benchmark Soils. Communications in Soil Science and Plant Analysis; 41:2532–2544. CR - [6] Goldberg, S. 1997. Reactions of boron with soils. Plant and Soil; 193:35–48. CR - [7] Memişoğlu, B.A. 2008. Treatment of soils contaminated with boron by green reclamation (phytoremediation) method. PhD Thesis, Ataturk University, Turkey. [8] Shaheen, R., Arefin, M.T., Mahmud, R. 2007. Phytoremediation of boron contaminated soils by naturally grown weeds. Journal of.Soil Nature; 1 (1):1-6. CR - [9] Rees, R., Robinson, B.H., Menon, M., Lehmann, E., Guunthardt-Goerg, M.S., and Schulin: R. 2011. Boron Accumulation and Toxicity in Hybrid Poplar (Populus nigra euramericana). Environmental Science and Technology; 45:10538–10543. CR - [10] Foote, F.J. 1932. Determination of boron in waters: Method for direct titration of boric acid. Industrial & Engineering Chemistry Analytical Edition; (4):39–42. [11] Clesceri, F.S., Greenberg, A.E., Eaton, A.D. 1999. Standard Methods for the Examination of Water and Wastewater, 20th edition, Water Environment Federation: American Water Works Association, Washington, DC, USA. CR - [12] Turan, M.D., Altundoğan, H.S. 2011. Use of Response Surface Methods (RSM) in Hydrometallurgical Research. Madencilik; 50:11-23. CR - [13] Kicsi, A., Cojocaru, C., Macoveanu, M., Bilba, D. 2010. Response surface methodology applied for zinc removal from aqueous solutions using sphagnum peat moss as sorbent. Journal of Environmental Protection and Ecology; 11(2):614–622. CR - [14] Korkmaz, M., Fil, B. A., Özmetin, C., Yaşar, Y. 2014. Full Factorial Design of Experiments for Boron Removal from Colemanite Mine Wastewater Using Purolite S 108 Resin. Bulgarian Chemical Communucation; 46:594–601. UR - https://doi.org/10.18466/cbayarfbe.961739 L1 - https://dergipark.org.tr/en/download/article-file/1857370 ER -