numerous adsorbents including activ

numerous adsorbents including activated carbon, SBA-15 silicas,
mesoporous manganites and mesoporous titania–silica–phosphonate
have been employed as adsorbents in SPE techniques due to
their unique large surface areas, well-defined pore sizes, high pore
volume and great diversity in surface functionalization (Chouyyok
et al., 2010; Lin, Ma, & Yuan, 2011; Liu, Hidajat, Kawi, & Zhao, 2000;
Nandi, Sarkar, Seikh, & Bhaumik, 2011). However, the application
of such adsorbents often requires post-treatment after adsorption.
Sometimes the complete separation and removal of adsorbents
from aqueous solutions can be difficult and can cause additional
environmental problems. Magnetic solid-phase extraction (MSPE)
using magnetic composites as adsorbents are one of the latest
developments in SPE techniques. The inherent characteristic of
magnetic properties ability has promoted an increasing application
of magnetic composites in many fields (Daneshvar Tarigh &
Shemirani, 2013; Huo & Yan, 2012; Mashhadizadeh, Amoli-Diva,
Shapouri, & Afruzi, 2014). For MSPE, the dispersed magnetic composites
can be separated from the matrix quickly in a magnet, and
redispersed in the eluent once the external field is removed.
Metal organic frameworks (MOFs), forming by the coordination
of a metallic center and an organic ligand, have proved to be a new
class of materials. The high porosity and specific surface of MOFs
has directed their potential applications toward catalysis, sensors,
separation, and drug delivery (Dhakshinamoorthy, Alvaro, &Garcia, 2011; Huxford, Rocca, & Lin, 2010; Petit, Levasseur,
Mendoza, & Bandosz, 2012; Yu et al., 2014). Moreover, MOFs also
show great promise in the analytical applications such as the capture
of heavy metal ions by the chelation coordination effect
between metal ions and functional group in the linker (Fang
et al., 2010; He et al., 2013; Yang et al., 2013). However, the use
of functional linkers is limited by the conventional solvothermal
procedure of MOFs. Postsynthetic modification has been utilized
as a powerful tool for introducing functionality to MOFs by covalent
reactions. The incorporation of functional groups on the linking
ligands can provide an opportunity to develop MOFs with a
variety of functionalities (Bernt, Guillerm, Serre, & Stock, 2011;
Gadzikwa et al., 2008; Jung et al., 2011).
Herein, we report the preparation of mercapto groups modified
magnetic metal organic frameworks (SH-Fe3O4/Cu3(BTC)2) adsorbents
and the potential application for the extraction of trace
heavy metal ions followed by flame atomic absorption spectroscopy
(FAAS). The adsorbent possesses large a surface area
because of the nanometer size. The superparamagnetic Fe3O4 contributes
to the rapid separation of the adsorbent from the matrix
solution. Mercapto groups provide more bonding sites for heavy
metals. Based on these considerations, extracting trace heavy metals
from water solutions can be readily achieved. To the best of our
knowledge, no research on the application of SH-Fe3O4/Cu3(BTC)2
composites for extraction and determination of trace lead in food
samples and certified reference material has been reported.