XAD resins as the copolymer backbon

XAD resins as the copolymer backbone for the immobilization
of chelating ligands have physical superiorities such
as porosity, uniform pore size distribution, high surface area,
durability, and chemical stability toward acids, bases and
oxidizing agents [7,8]. Typical preconcentration factors of
Amberlite XAD-2 resins functionalized with chelating ligands
such as pyrocatechol [9], PAN, salicylic acid, chromotropic
acid, pyrocatechol violet [10] and tiron [11] range
between 80 and 200 for a number of metal(II) ions, thereby
significantly decreasing the detection limits that can normally
be acquired by spectrophotometry and FAAS. In the
literature, many chelating ion-exchangers are described that
were synthesized from XAD-2, XAD-4 and XAD-7 copolymers
suitable for metal ion separation and preconcentration
from aqueous solution [9]. Ni, Co, Cu, and V are a few examples
of trace elements that have been preconcentrated and
determined using XAD resins functionalized with PAN [12],
TAC [13], calmagite [8] and 5-Br-PADAP [7], respectively.
Two broad classes of methods are generally applied to the
preparation of chelating exchanger resins: sorption of the
chelating ligand on the polymer matrix, and covalent linkage
of the ligand to the polymer backbone via intermediary
functional groups such as –N=N–, produced as the diazotization
product of the polymer, or –CH2–, formed from Cl2
+ formaldehyde or methylene chloride reaction [14]. The
second method, based on covalent binding of the ligand, produces
a much more stably-bound substrate resistant to leaching,
but the resulting metal retention capacities are only at
medium levels. The capacities can be increased by more populated
functional group binding to the suitably cross-linked
polymer. If the ligating groups belong to molecules of relatively
small size, this aim may be better accomplished
[15].