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POLİAMİN -POLİÜRE REÇİNESİNİN SENTEZLENMESİ VE Cd(II) İYONLARININ SULU ÇÖZELTİLERDEN ADSORPSİYONLA GİDERİLMESİNDE KULLANILMASI

SYNTHESIS OF POLYAMINE-POLYUREA RESIN AND USING FOR REMOVAL OF CADMIUM (II) IONS FROM AQUEOUS SOLUTIONS

Journal Name:

  • Sakarya Üniversitesi Fen Bilimleri Enstitüsü Dergisi

Publication Year:

  • 2009

Key Words:

Keywords (Original Language):

Author NameUniversity of AuthorFaculty of Author
Abstract (2. Language): 
Polyamine-polyurea chelating resin was synthesized from TDI(toluendiizosiyanat) and TETA(Trietilentetraamin) and it was used in removal of cadmium (II) ions from aqueous solutions by adsorption. By using batch method, the effect of pH, adsorbent dosage, contact time and initial concentration on adsorption were investigated. The adsorbent exhibited good sorption potential for Cd (II) ions in these conditions: 60 minutes of contact time in pH:6,0 with adsorbent dosage 0,5 g/100 mL. Adsorption results were applied to Langmiur and Freundlich isotherm equations. As results of isotherm investigations, the adsorption results were fitted well to Langmiur isotherm adsorption model which describes chemisorption with correlation coefficient of 0,998. Maxsimum adsorption capacity 7,305 mg/g was determined. The results of the experiments show that the resin has high adsorbing capacity for Cd(II) ions.
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Abstract (Original Language): 
Sulu çözeltilerden Cd (II) iyonlarının adsorpsiyonla giderilmesinde kullanılan poliamin-poliüre reçinesi TDI (toluendiizosiyanat) ve TETA (trietilentetraamin) kullanılarak hazırlanmıştır. Adsorpsiyona pH değişimi, adsorbanın dozu, karıştırma süresinin ve başlangıç derişiminin etkisi incelenmiştir. Adsorban pH 6,0’ da, 0,5 g/100 mL reçine dozunda ve 60 dakika karıştırma süresinde Cd (II) iyonları için iyi sorpsiyon özelliği göstermiştir. Deney sonuçlarının Langmiur ve Freundlich denge eşitliklerine uygunluğunun araştırılması sonucunda kemisorpsiyonu açıklayan Langmuir denge eşitliğine 0,998 korelasyon katsayısıyla uyduğu görülmüştür. Maksimum adsorpsiyon kapasitesi 7,305 mg/g olarak bulunmuştur. Sonuçlar sentezlenen reçinenin yüksek adsorpsiyon kapasitesine sahip olduğunu göstermektedir.
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REFERENCES

References: 

[1] RAO, M.M., RAMESH A., RAO, G.P.C.,
SESHAIAH, K., ‘Removal of Copper and
Cadmium from the Aqueous Solutions by
Activated Carbon derived from Ceiba
Pentandra Hulls’, Journal of Hazardous
Materials B129 (2006) 123-129.
[2] RAMOS, R.L., Water Sci. Technol. 35 (1997)
205.
[3] ATIA, A.A., DONIA, A.M., YOUSIF, A.M.,
‘Synthesis of Amine and Thio Chelating
Resins and Study of Their Interaction with
Zinc (II), Cadmium (II) and Mercury (II) Ions
in Their Aqueous Solutions’, Reactive &
Functional Polymers 56 (2003) 75-82.
[4] TEKER, M., IMAMOGLU M. and
SALTABAS O., ‘Adsorption of Copper and
Cadmium Ions by Activated Carbon from Rice
Hulls’, Turk. J. Chem. 1999; 23 (2):185-191.
[5] ARSLAN, M., TEMOÇİN, Z., YİĞİTOĞLU,
M., “Removal of Cadmium(II) from Aqueos
Solutions Using Sporopollenin” Fresenius
Environmental Bulletin, PSP. 2004;13(7).
[6] KURNIAWAN, T.A., CHAN, G.Y.S., LO, WH.,
BABEL, S., Physico-Chemical Treatment
Techniques for Wastewater Laden with Heavy
Metals, Chemical Engineering Journal,
2006;118(1-2):83-98.
[7] MURATHAN, A., Removal of Heavy Metal
Ions from Aqueous Solutions in Fixed Beds by
Using Horse Chestnut and Oak Valonia,
Fresenius Environmental Bulletin, PSP. 2005;
14(4).
[8] YU, L.J., SHUKLA, S.S., DORRIS, K.L.,
SHUKLA, A. and MARGRAVE, J.L.,
Adsorption of Chromium from Aqueos
Solutions by Mapple Sawdust, Journal of
Hazardous Materials, 2003; B100:53-63.
[9] KOJIMA, T., SOWA, T., KODAMA,
S.,SATO, M., SHIGETOMI, Y.,
YAMAMOTO, Y., Adsorption Behaviour and
Seperation of Copper(II) Ions on Cellulose
Triacetate Polymer Containing α-Hydroxy
Oxime Compounds, Analytica Chimica Acta,
1992; 264, 59.
[10] LEZZI, A., COBIANCO, S., ROGGERO, A.,
Synthesis of Thiol Chelating Resins and Their
Adsorption Properties Toward Heavy Metal
Ions, Journal Polymer Science, Part A, 1994;
22, 1877.
[11] LEZZI, A., COBIANCO, S., ‘Chelating
Resins Supporting Dithiocarbamate and
Methylthiourea Groups in Adsorption of
Heavy Metals Ions’ Journal Applied Polymer
Science, 1994; 54, 889.
[12] LIAN, N., CHANG, X., ZHENG, H., HE, Q.,
JIANG, N., SI, H., Preconcentration of Trace
Metals with Poly(Acryl-Benzoylamidrazone-
Acryl-Benzoylhydrazine) Chelating Fiber,
Solvent Extraction and Ion Exchange, 2006;
24: 639-652.
[13] SHIN, D.H., KO, Y.G., CHOIU, S., KIM,
W.N., Synthesis and Characteristics of Novel
Chelate Fiber Containing Amine and Amidine
Groups, Polym. Adv. Technol. 2004; 15:459-
466.
[14]
[15]
BIÇAK, N., ATAY, T., KOZA, G., ‘Removal
of Transition metal cations and Their
Counteranions by Crosslinked Epoxy-Amine
Polymer’ Journal of applied polymer Science,
Vol. 68, 103-109 (1998)
REDDY, A.R., REDDY, K.H., ‘Heavy Metal
Ion Uptake Properties of Polystyrene-
Supported Chelating Polymer Resins’ Indian
Acad. Sci. (Chem. Sci.), Vol. 115, No.3, June
2003, pp 155-160
[16] CHEN, C-Y., LIN, M-S., HSU, K.R.,
Recovery of Cu(II) and Cd(II) by a Chelating
Resin Containing Aspartate Groups, Journal of
Hazardous Materials, 2008; 152(3):986-993.
[17] DINGMAN, Jr.J., SIGGIA, S., BARTON, C.,
HISCOCK, K.B., Concentration and
Seperation of Trace Metal Cations by
Complexation on Polyamine-Polyurea
Resins, Analytical Chemistry, 1972; 44(8)
[18] KURNIAWAN, T.A., CHAN, G.Y.S., LO, WH.,
BABEL, S., Physico-Chemical Treatment
Techniques for Wastewater Laden with Heavy
Metals, Chemical Engineering Journal,
2006;118(1-2):83-98.
[19] TUNAY, O., KAPDAŞLI, N.I., Hydroxide
Precipitation of Complexed Metals, Waters
Research, 1994; 288(10): 2117-2124.[20] PETRUCCI, R.H., HARWOOD, W.S.,
HERRING, F.G., General Chemistry Principles
and Modern Applications, 8th Ed., Prentice
Hall, 2002.
[21] CHARERNTANYARAK, L., Heavy Metals
Removal by Chemical Coagulation and
Precipitation, Water Science and Technology,
1999; 39(10-11):135-138.
[22] PAPADOPOULOS, A., FATTA, D.,
PARPERIS, K., MENTZIS, A.,
HARALAMBOUS, K.J., LOIZIDOU, M.,
Nickel Uptake from a Wastewater Stream
Produced in a Metal Finishing Industry by
Combination of Ion-exchange and Precipitation
Methods, Seperation and Purification
Technology, 2004; 39(3):181-188.
[23] SKOOG, D.A., WEST, D.M., HOLLER, F.J.,
Fundamentals of Analytical Chemistry,
Saunders College Publishing, 7th Ed., 0-03-
005938-0, 1996.
[24] BERKEM, A.R., BAYKUT, S., ‘Fizikokimya’
sayfa: 787-816. İstanbul Üniversitesi Yayınları.
Sayı: 2345. Fatih Yayınevi Matbaası 1977.
[25] NG, J.C.Y., CHEUNG, W.H., McKAY, G.,
‘Equilibrium Studies fort he Sorption of Lead
from Effluents Using Chitosan’ Chemosphere
2003; 52: 1021-1030.
[26] ATKINS, P.W., ‘Physical Chemistry’ 6th Ed.
Oxford University Press 1998.
[27] AHALYA, N., KANAMADI, R.D.,
RAMACHANDRA, T.V., ‘Biosorption of
Chronium(VI) from Aqueous Solutions by the
Husk of Bengal Gram(Cicer Arientinum),
Environmental Biotechnology, 2005; 8(3).
[28] ALKAN, M., DEMİRBAŞ, Ö., DOĞAN, M.,
Adsorption Kinetics and Thermodynamics of
an Anionic dye onto Sepiolite, Science Direct,
Microporous and Mesoporous Materials 2007;
101:388-396.
[29] INGLEZAKIS, V.J., POULOPOULOS, S.G.,
’Adsorption, Ion Exchange and Catalysis’
Elsevier 1st Edition, 2006.
[30] PEHLİVAN, E., ALTUN, T., Ion-exchange of
Pb+2, Cu+2, Zn+2, Cd+2 and Ni+2 ions from
Aqueous Solution by Lewatit CNP 80, Journal
of Hazardous Materials, 2007; 140:299-307.
[31] CHEN, C-Y., LIN, M-S., HSU, K.R.,
Recovery of Cu(II) and Cd(II) by a Chelating
Resin Containing Aspartate Groups, Journal of
Hazardous Materials, 2008; 152(3):986-993.

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