Anaerobic digestion of organic wast

Anaerobic digestion of organic wastewater sludge has shown to
be one of the most significant processes to reduce pollution (atmospheric
and terrestrial) and produce fuels (e.g. methane) [1].Most of
the models reported in the literature refer to a single-stage, anaerobic
digestion process, where hydrolysis, acidogenesis, acetogenesis
and methanogenesis all take place in the same reactor. In these
conditions, the understanding of the chemical and biological processes
acting together is extremely difficult and it has actually been
approached by working on single bacterial strains or under artificial
conditions [2]. To recall a pertinent example, in order to maintain an
appropriate environment for microorganisms in a whole-process
single reactor, volatile fatty acid (VFA) production and utilization
must be balanced, since a high VFA production might lead to a reactor
failure [3]. Two-stage anaerobic processes have been proposed
for dividing VFA and methane forming stages, so as to optimize each
stage [4–7]; this, in fact, would allow a better analysis of the chemical
process involved. Every decomposition stage of sludges is characterized
by quali-quantitative variations of organic carbon. These
∗ Corresponding author. Fax: +39 051 2096203.
E-mail address: ornella.francioso@unibo.it (O. Francioso).
changes can be directly identified by using a multiple analytical
approach similar to that applied to chemical modifications occurring
in the compost [8] or soil organic matter transformation [9].
The use of thermogravimetric analysis (TGA) has recently been
extended to the study of sewage sludge [10]. This technique
combined with differential thermal analysis (DTA) or differential
scanning calorimetry (DSC) has enabled to follow the progress of
organic matter stabilization during composting processes [9–14].
The common advantage of these techniques is the simplicity of
sample preparation. By combining these techniques with diffuse
reflectance infrared Fourier transform (DRIFT) spectroscopy, a simple
and rapid method to characterize the functional groups of
composts [8,9] and soil organic matter [9,15], it is possible to obtain
additional information about the structure of organic molecules
involved in the transformation process.
Likewise, stable carbon isotope analysis represents a powerful
monitoring tool to provide in situ detection of the organic matter
transformation in methane [16], biodegradation of chlorinated
hydrocarbons [17] and bacterial oxidation of methane [18]. Therefore,
the ı13C technique might improve our understanding of the
transformation, utilization and stabilization of organic C during
anaerobic digestion of wastes. Since a number of factors influence
13C fractionation