Impact of the inoculum composition on the structure of the total and active community and its performance in identically operated anaerobic reactors.

Anaerobic digestion (AD) is a biological process that is acquiring increasing attention for both solid waste and wastewater treatment, as well as for the production of valuable chemicals. Despite the importance of the inoculum, the relationship between inoculum community composition, reactor performance, and reactor community composition remains vague. To understand the impact of the starting community on the composition and functioning of the AD microbiome, we studied three sets of biologically replicated AD reactors inoculated with different communities, but operated identically, targeting both total and active community compositions. All reactors performed highly similar regarding volatile fatty acid and methane production. The community analyses showed reproducible total and active community compositions in replicate reactors, indicating that particularly deterministic factors shaped the AD community. Moreover, strong variation in community composition between the differently seeded reactors was observed, indicating the role of inoculum composition in community shaping. In all three reactor sets, especially species that were low abundant or even not detected in the inoculum contributed to the reactor communities, supporting the importance of functional redundancy and high diversity in inocula used for AD seeding. The careful start-up of the AD process using initially low organic loading rates likely contributed to the successful assembly of initial low-abundance/rare species into a new cooperative AD community in the reactors.

Systems analysis of digestate primary processing techniques.

In this paper, we performed technology assessment and systems analysis of primary digestate processing techniques to provide a comprehensive analysis of their environmental and cost performance. We compiled more than 100 observations from large-scale biogas plants and considered digestate based on manure, crops and agro-wastes, and food waste under the geographical contexts of Sweden and Belgium. Centrifuge, screw press, and rotary drum were identified as suitable primary processing techniques. We analyzed the climate impact, energy use, and operational cost of digestate management under these scenarios: no processing, partial processing (solid-liquid separation) and full processing (solid-liquid separation followed by ammonia stripping). As expected, the suitable digestate processing varied with the context, transport was often the most critical cost factor, and emissions from storage reduced the climate savings from the use of biofertilizers. However, treating liquid fraction became a main contributor to cost and climate impact under the Belgian conditions. Consequently, the possibility for local application of liquid fraction as biofertilizer could prevent costs and impacts associated with its further treatment. The main novelty of this work is in its integrative and comprehensive approach toward the choices and impacts of primary processing of digestate. We tried to bridge many individual case studies, drew from experiences of biogas plants in different geographical contexts, assessed suitable processing techniques for different digestate types, and analyzed the environmental impacts and cost of digestate management from a life cycle perspective. We believe that such integrated approaches would help decision-making for increased sustainability of the biogas sector.