Litcius/Paper detail

Anaerobic sludge digestion enhancement with bioelectrochemical and electrically conductive materials augmentation: A state of the art review

Arianna Callegari, Matteo Tucci, Federico Aulenta, Carolina Cruz Viggi, Andrea G. Capodaglio

2025Chemosphere17 citationsDOIOpen Access PDF

Abstract

Excess biological sludge processing and disposal have a significant impact on the energy balance and economics of wastewater treatment operations, and on receiving environments. Anaerobic digestion is probably the most widespread in-plant sludge processing method globally, since it stabilizes and converts biosolids organic matter into biogas, allowing partial recovery of their embedded chemical energy. A considerable number of studies concerning applicable techniques to improve biogas production, both in quantity and quality, include pre-treatment strategies to promote biosolids disintegration aimed at the release and solubilization of intracellular energy compounds, inorganic/biological amendments aimed at improving process performance, and sludge thermal pre-treatment. As for in-process amendments, iron, micro and macro-nutrients, ashes from waste incineration and nanoparticles addition have been studied for the improvement of enzymatic reactions. Recently, use of electrically conductive materials has been credited with the possibility to accelerate and stabilize the conversion of organic substrates to methane. The possibility of increasing both biogas generation and its relative biomethane content by interfacing anaerobic digestion with bioelectrochemical systems was also postulated. This review addresses the research gap surrounding the integration of anaerobic digestion with novel technologies, particularly bioelectrochemical systems, to enhance biogas production and methane enrichment. While existing studies focus on pre-treatment and in-process amendments, the feasibility, mechanisms, and benefits of such integration remain underexplored. By critically evaluating the current state of the art, this review identifies the potential of bioelectrochemical integration to improve energy recovery and process stability, while highlighting key challenges and research needs for advancing these technologies toward practical implementation. • AD's biogas production by sludge pretreatment aims at release and solubilization of intracellular matter for easier availability • Interspecies electron transfer allows anaerobic bacteria to share reducing equivalents to drive methanogesis • Non-biological electric conductive nanoparticles promote interspecies electron transfer in syntrophic cultures • Biolelectrochemical systems integration in AD have shown improved process performance and higher biogas methane fraction • Combination of conductive nanoparticles and bioelectrochemical systems could be a suitable strategy to improve AD performance and methane recovery

Topics & Concepts

Anaerobic digestionBiosolidsBiogasWaste managementEnvironmental scienceEnergy recoverySewage treatmentMicrobial fuel cellBiodegradable wasteWaste treatmentSewage sludgeMethaneChemistryEngineeringPhysical chemistryStatisticsElectrodeMathematicsEnergy (signal processing)AnodeOrganic chemistryMicrobial Fuel Cells and BioremediationAnaerobic Digestion and Biogas ProductionMembrane Separation Technologies