A method of copper (II) ion preconcentration and separation from other ions by using a column containing fatty hydroxamic acids - loaded Amberlite XAD 4 resin (FHA-Amb) is described. Several factors, which affect the separation and preconcentration efficiency such as pH, sample volume, and concentration of eluent and flow rate, have been investigated.  A quantitative recovery of copper (II) ion from FHA-Amb resin column was obtained using 10% HNO₃ solutions as eluent with a preconcentration factor of 60. A method for separation of Cu(II) from Zn(II) and Cd(II) is proposed.  A rapid sample throughput, a clean separation, a high preconcentration factor and simplicity are the main advantages in these analytical procedures.

[1] Jain, V.K., Sait, S.S., Shrivastav, P., and Agrawal, Y.K., 1997, Talanta, 45, 397-404.

[2] Ferreira, S.L.C., de Brito, C.F., Dantas, A.F., de Araujo, N.M.L., and Costa, A.C.S., 1999, Talanta, 48, 1173-1177.

[3] Kabay, N., Demircioglu, M., Ekinci, H., Yuksel, M., Saglam, M., and Streat, M., 1998, Reactive & Functional Polym., 38, 219-226.

[4] Anthemidis, A.N., Zachariadis, G.A., and Stratis, J.A., 2002, Talanta, 58, 831-840.

[5] Ferreira, S.L.C., Ferreira, J.R., Lemos, V.A., Dantas, A.F., de Araujo, N.M.L., and Costa, A.C.S., 2000, Talanta, 50, 253-1259.

[6] Jain, V.K., Handa, A., Sait, S.S., Shrivastav, P., and Agrawal, Y.K., 2001, Anal. Chim. Acta, 429, 237-246.

[7] Greenwood, N.N., and Earnshow, A., 1984 Chemistry of Elements, Pergamon, New York, 1364-1369.

[8] Franson, M.A.H., 1995, Standard Methods for Examination of Water and Waste Water, 19^th ed. American Publication Health Association, Washington, DC, 3-68.

[9] San Andres, M.P., Marina, M.L., and Vera, S. 1995, Analyst, 120, 255.

[10] Tait, B.K., Mdlalose, K.E., and Taljaard, I., 1995, Hydrometalurgy, 38, 1-6.

[11] Kara D., and Alkan M., 2002,Microchemical Journal, 71, 29-39.

[12] Eidecker, R., and Jackwerth, E., 1988, Z. Anal. Chem. 328, 401-406.

[13] Say, R., Birlik, E., Ersoz, A., Yilmaz, F., Gedikbey, T., and Denizli, A., 2003, Anal. Chim. Acta, 480, 251-258.

[14] Wang, X., Chen, Q., Yin, Z., Zhang, P., Long, Z., and Su, Z., 2003, Hydrometallurgy, 69, 39-44.

[15] Singh, R., and Prasad, B.B., 2000, Process Biochem., 35, 897-905.

[16] Sarangi K., and Das, R.P., 2003, Hydrometallurgy, 2158, 1-8.

[17] Olesik, J.W., and Moore, Jr, A.W., 1990, Anal. Chem. 62, 840-845.

[18] Ramesh, A., Mohan, K.R., and Seshaiah, K., 2002, Talanta 57, 243-252.

[19] Dev, K., Pathak, R., and Rao, G.N., 1999, Talanta, 48, 579-584.

[20] Uzun, A., Soylak, M., and Elci, L., 2001, Talanta, 54, 197-202.

[21] Suhendra, D., Wan Yunus, W.M.Z., Haron, M.J., Basri M., and Silong S., 2005, J. Oleo Sci., 54: 1, 33-38.

[22] Haron, M.J., Wan Yunus, W.M.Z., Desa, M.Z. and Kassim, A., 1994, Talanta, 41, 5: 805-807.

[23] Tan, B.K., and Oh, C.H., 1981 Malaysian Palm Oil Chemical and Physical Characteristic, PORIM Technology 3, Kuala Lumpur, Malaysia.