Pyrite, with chemical formula FeS2,

Pyrite, with chemical formula FeS2, is a very common sulfide
mineral and is found in a wide range of geological sites [1]. In
countries such as China, pyrite is very abundant and dominant sulfide
compound in coal. Although it is only composed of a relatively
small portion of coal, it almost influences and decides the operational,
environmental and economical performance of handling
and utilizing processes of coal [2,3]. Information about the abundance,
distribution and origin of sulfur in coals is important in
coal combustion because the sulfur oxides released can be a major
source of acid rain [4]. This is also because pyrite releases a major
source of SO2 (acid rain precursor) in the combustion process and
many evidences also suggest that it may possibly possess a catalytic
role in coal liquefaction and gasification processes. Not only does
pyrite present itself in many different environments, it exhibits surface
chemistry that can profoundly affect the very environment in
which it is present. It might be one of the most striking examples
of how the reactivity of pyrite can affect an environment is associated
with anthropogenic activities. It is reported that the thermal decomposition of pyrite in coal mining sites leads to the devastating
environmental problem [5]. Furthermore, pyritic and organic
sulfur are the two major forms of sulfur in coal. Their behavior
is very important in coal utilization [6]. The thermal stability of
coal-derived pyrite (and other sulfides) plays a large role in the
commercially important processes of mineral benefaction and the
separation of sulfides from coal the evolution process of SO2.
Thermogravimetric analysis is used widely in thermal analysis
and kinetics parameters study of pyrite under both nitrogen
and air atmospheres [1,7–10]. For decomposition, different heating
rates are carried out to obtain the kinetic model [11–13]. For
oxidation, different oxygen concentrations and heating rates are
taken into account by thermogravimetry (TG) analysis [12,14]. But
the composition of evolved gas in each mass loss steps cannot be
observed only by TG. On the other hand, Fourier transform infrared
spectroscopy (FTIR) results can be used to evaluate the functional
groups and prove the existence of some emissions [15–17]. However,
TG combining with FTIR is a useful tool in dynamic analysis
as it monitors continuously both the time dependent evolution of
the gases and the mass of the non-volatile minerals/materials. It
has already been used widely to investigate the thermal behavior
of minerals [18–24] and polymers thermal degradation [25–27], as
well as to forecast the hazardous emissions that may be produced
in the case of major accidents [28,29]. But very limited studies were
conducted using TG combining with FTIR on the thermal analysis
of coal-derived pyrite.