Abstract
The necessity of developing renewable energy sources has contributed to increasing interest in developing the anaerobic digestion for producing biomethane since it both provides green energy and reduces disposal treatment. In this regard, to assure efficient water utilization by finding alternative water sources, sewage sludge collected from the wastewater treatment plant (WWTP) was recently investigated because it could represent a suitable resource for producing biomethane within the context of a circular economy. Therefore, this study aims at improving the current knowledge on the feasibility of biomethane production from sewage sludge by optimizing the logistic-supplying phase. In this regard, a GIS-based model was developed and applied to the Emilia-Romagna region to consider the existing networks of WWTPs and biogas systems to valorize sewage sludge for bioenergy production and minimizing environmental impact. The results of the GIS analyses allowed to localize the highest productive territorial areas and highlighted where sewage sludges are abundantly located and could be better exploited within agricultural biogas plants. Finally, the achieved results could help plan suitable policy interventions that are centered on biomass supply and outputs diversification, governance, and social participation, since the regulatory framework could play a crucial role in planning the reuse of these wastes for developing a more sustainable biomethane sector in line with the green economy goals.
Highlights
The world population is estimated to reach 9.8 billion by 2050 and around 11.2 billion by 2100 [1]
To assure efficient water utilization by finding alternative water sources, sewage sludge collected from the wastewater treatment plant (WWTP) was recently investigated because it could represent a suitable resource for producing biomethane within the context of a circular economy
As reported by the Istat database related to the 2015 year, 2037 WWTPs are located in the Emilia-Romagna region, and among these, 66% is represented by the primary sector, 22% by secondary sector, and 12% by tertiary one
Summary
The world population is estimated to reach 9.8 billion by 2050 and around 11.2 billion by 2100 [1] With this increasing population, a significant amount of fuel may be in demand to aid the energy requirements in the coming years [2]. Water sustainability is among the most discussed sustainability issues in the last years in which every applicable sustainability principle has been adopted for water from reuse to recycle [8,9] In this regard, through the concept of the circular economy, which aims for recovery/reuse strategies, new innovative technologies/processes for efficient water utilization, finding alternative water sources (i.e., mainly treated urban wastewater), and closing the water-related loops to balance water demand and supply have been triggered [10]
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