Evaluation of H2 supplementation in in situ biomethanation using fed-batch reactors for paper industry wastewater treatment

Background This study investigated in situ biomethanation as a biogas upgrading strategy by injecting hydrogen (H 2 ) into anaerobic fed-batch reactors treating wastewater from the pulp and paper industry. Methods Granular sludge was used as inoculum and H 2 was supplied at two pressures (0.6 and 0.9 bar overpressure in CB and CC assays, respectively) to evaluate its impact on treatment efficiency, methane (CH 4 ) production, and microbial community dynamics compared to control reactors (CA sets) after an adaptation phase with feeding wastewater only. Results The CH 4 production increased during the first two feeding cycles with H 2 supplementation accompanied by a reduction in CO 2 emissions. However, this was transient and at the end of cycle 7 acid accumulation (mainly acetic and propionic acids) and reduced CH 4 production was observed in both H 2 -supplemented assays. Microbial community structure changed first as a function of new stirred reactor conditions and later according to amount of H 2 addition resulting in three clearly separated groups of communities. The family Syntrophobacteraceae responsible for propionate degradation declined in all reactors due to operational changes and following microbial succession. In control reactors it was out-competed by members of Geobacteraceae and Desulfobulbaceae. In CB and CC assays, Ethanoligenenaceae, Bacillaceae, Kosmotogaceae, Anaerolineaceae, and Anaerolineaceae families were enriched as a result of H 2 supplementation. The most abundant methanogens were affiliated to the acetotrophic Methanothrix and the hydrogenotrophic Methanobacterium in all batch reactors. Upon H 2 addition the relative abundance of Methanobacterium increased and became predominant in later cycles of CB and CC sets. Despite this shift, both genera coexisted throughout the experiments, suggesting that multiple metabolic pathways contributed to CH 4 production under H 2 -enriched conditions. Conclusions Although the process demonstrated potential for simultaneous biogas upgrade and wastewater treatment, the overall performance was negatively influenced by increased H 2 pressure. This highlights that proper H 2 dosing and microbial monitoring are critical to ensure process stability for in situ biomethanation systems. Considering the fragile balance of the investigated wastewater treatment process an ex situ upgrade of biogas using a separate reactor is recommended.