The environmental challenge nowaday

The environmental challenge nowadays is to develop green
technologies that are less aggressive toward the biota of the receiving
ecosystems. In this regard, non-thermal plasma (NTP) is an
emergent technology which can be applied to both aqueous and
gaseous phases. It has been shown to lead to chemical activation of
a system [1] through the production of active species in situ (e.g.,
ions, radicals, molecular species, atomic species, shock waves, UV
light), and does not require the use of additional chemicals.
A successful example of the use of NTP pollution control is in
the treatment of water contaminated with organic dyes. In general, the removal efficiency can be increased by changing the gas composition
(e.g., Ar, O2, N2, air), power applied, and solution temperature
[1], and also with the addition of homogeneous [2] and heterogeneous
[3] catalysts. The combination of NTP with catalysts has been
extensively adopted to enhance pollutant removal, and different
catalysts have been studied for this purpose, such as TiO2 photocatalyst
[4–6], alumina and silica gel [7], Fe2+ [2], Fe3O4 [8] and
activated carbon [3], etc. However, other catalysts need to be studied
to enhance the synergetic effect between these techniques and
herein we propose the use of mineral pyrite as a catalyst to remove
methylene blue (MB) from solution.
Mineral pyrite, or iron pyrite, is an iron sulfide with the formula
FeS2 commonly found in southern Brazil and its occurrence is
related to coal mining activities where it is present as an impurity.
Some papers [9,10] have demonstrated that pyrite spontaneously
generates H2O2 and OH when in contact with water. This suggests
that pyrite could be used as a catalyst in combination with NTP reactors to enhance organic pollutant removal. However, byproducts
present in the treated solution generated by the
NTP–pyrite system, as well as its possible effects on the environment,
must be known in order to better explore the potential of
this technique for water pollution control.
In this study, methylene blue (MB) degradation in the aqueous
phase applying an electrical discharge NTP above the solution
surface was investigated using three different feed gases: nitrogen
(N2), argon (Ar), and oxygen (O2). Also, the hydrogen peroxide
(H2O2) concentration in water produced by the NTP discharge was
determined. In order to enhance the dye degradation rate using O2
as the feed gas, pyrite was added to the reactor and its effect was
studied. The results for the total organic carbon (TOC) content and
the acute toxicity (tested against Artemia sp. microcrustaceans) of
the dye solutions treated with and without the pyrite catalyst were
compared with similar data for the stock solution in order to obtain
an insight into the environmental impact of NTP–pyrite treatment.
Finally, electrospray ionization mass spectrometry (ESI-MS) analysis
of the treated samples was also performed to identify some
intermediates involved in the MB degradation.