conditions. The solid matrix was fi

conditions. The solid matrix was filtered and washed with distilled water.
The sorbed metal ions on the resin were desorbed with 10 mL of 1 M
HNO3and determined by ICP-AES. The sorption capacities in mg g

1
are 4.2 for Cd(II), 4.4 for Cu(II), 3.9 for Ni(II), and 4.8 for Pb(II),
respectively.
’RESULTS AND DISCUSSION
IR Spectral Analysis of NPTT and Amberlite XAD-2-NPTT.
FT-IR analysis of NPTT and the functionalized Amberlite XAD-2-NPTT were carried out with as potassium bromide pellets. The
FT-IR spectrum of NPTT showed bands at 3417, 3051, 1616,
1258, and 1152 cm

1
due to N
H, Ar
H, CdN, CdS,
and C
N stretching, respectively. In the FT-IR spectrum
of functionalized Amberlite XAD-2-NPTT, bands appeared at
3394, 2948, 1592, 1523, 1228, and 1149 cm

1
due to N
H,
Ar
H, CdN, NdN, CdS, and C
N stretching, respectively
(Figure 1). These similarities between the spectra of ligand
(NPTT) and the modified resin support the functionalization
of Amberlite XAD-2 with NPTT through azo spacer.
Effect of pH.pH is one of the important factors affecting the
efficiency of retention/elution of metal ions by solid support.
8
The formation of metal complexes and their stabilities in aqueous
solutions are strongly related to the pH of the medium. The effect
of pH was studied by varying the pH in the range of 2.0
9.0
(Figure 2). To evaluate the effect of pH on the extraction
efficiency, the pH of the 600 mL sample solutions containing
50μg each of Cd(II), Cu(II), Ni(II), and Pb(II) was adjusted in
the range of 2.0
9.0, and the recommended procedure was
applied. The solutions were passed through the column at a flow
rate of 2.5 mL min

1
. The metal ions sorbed onto resin were then
eluted by an appropriate eluent and determined by ICP-AES. In
all of the cases, metal retention by the functionalized Amberlite
XAD-2-NPTT was increased with increasing pH and reached a
maximum (pH 6.0) after which the retention decreased. On the