Glass is an important and widely us

Glass is an important and widely used material. It is a chemical mixture of oxides such as SiO2,Al2O3,CaO,MgO,Na2O, PbO, and B2O3.Each
oxide confers different characteristics and properties to glass. Because
the properties of glasses differ depending on their components, determination of chemical composition may provide important information
about glass samples. For example, analytical data from glass analyses
could be used to conduct archeometric studies[1–4], obtain historical
information or perform forensic science studies[5,6].
Elemental analyses of glass sample can be conducted by neutron
activation[7],X-rayfluorescence[8–10], scanning electron microscopy
(SEM)[8,10,11], inductively coupled plasma optical emission spectroscopy (ICP-OES)[11,12], inductively coupled plasma mass spectrometry
(ICP-MS)[8,10,11], laser ablation inductively coupled plasma mass
spectrometry (LA-ICP-MS)[11–14], and atomic absorption spectrometry (AAS)[8,15–17].
Fuller and Whitehead determined iron, copper, nickel, cobalt, manganese in sodium-calcium silicate glass and sodium borosilicate glass
by AAS, with a Massmann-type graphite furnace after the separation
of the metal diethyldithiocarbamates into isobutyl methyl ketone[15].
Guadagnino et al. determined selenium in glass by graphite furnace
atomic absorption spectrometry (GFAAS) after extraction with
dithizone and hydride generation by AAS after HNO3-HClO4-HF digestion[16]. Miller-Ihli studied the Cr determination in glass materials by
slurry sampling electrothermal AAS[18]. Headridge and Riddington
used an AAS with an induction or resistively heated furnace for the
determination of silver, lead and bismuth in 0.1–10-mg samples of standard, forensic, archaeological and ancient stained glass added directly to
the furnace. They constructed the calibration graphs of peak area versus
the mass of trace element by using NBS standard glasses for silver, lead
and standard solutions of bismuth nitrate[17].
In electrothermal atomic absorption spectrometry (ETAAS), solid
samples may be introduced into the graphite furnace in three ways.
(i) Liquid: samples are completely digested using acids, mostly inorganic acids, and oxidants with/without heating and are then pipetted into
the furnace using auto samplers. (ii) Slurry technique: samples are
finely ground and then dispensed in a simple liquid, mostly water. A
surfactant (e.g., Triton X-100) is added, and effective mixers (vortex,
ultrasonic blades, etc.) are used for the homogenization and stabilization of the slurry. The samples are then introduced into the furnace
using liquid auto samplers. (iii) Solid sampling technique: samples are
finely ground and directly introduced into the furnace.
Direct SS AAS has been recently developed and used for trace element determination in many different samples[19–30]. In this technique, the sample dissolving step is avoided, and the contamination
risk, errors and analysis time are reduced. SS GFAAS has several