Zagrodnik Roman, Seifert Krystyna
Faculty of Chemistry, Adam Mickiewicz University , Poznań , Poland.
Pol J Microbiol. 2020 Sep;69(1):109-120. doi: 10.33073/pjm-2020-015. Epub 2020 Mar 11.
Hydrogen produced from lignocellulose biomass is deemed as a promising fuel of the future. However, direct cellulose utilization remains an issue due to the low hydrogen yields. In this study, the long-term effect of inoculum (anaerobic sludge) heat pretreatment on hydrogen production from untreated cellulose and starch was evaluated during repeated batch processes. The inoculum pretreatment at 90°C was not sufficient to suppress H consuming bacteria, both for starch and cellulose. Although hydrogen was produced, it was rapidly utilized with simultaneous accumulation of acetic and propionic acid. The pretreatment at 100°C (20 min) resulted in the successful enrichment of hydrogen producers on starch. High production of hydrogen (1.2 l H/l) and H yield (1.7 mol H/mol) were maintained for 130 days, with butyric (1.5 g/l) and acetic acid (0.65 g/l) as main byproducts. On the other hand, the process with cellulose showed lower hydrogen production (0.3 l H/l) with simultaneous high acetic acid (1.4 g/l) and ethanol (1.2 g/l) concentration. Elimination of sulfates from the medium led to the efficient production of hydrogen in the initial cycles - 0.97 mol H/mol (5.93 mmol H/g). However, the effectiveness of pretreatment was only temporary for cellulose, because propionic acid accumulation (1.5 g/l) was observed after 25 days, which resulted in lower H production. The effective production of hydrogen from cellulose was also maintained for 40 days in a repeated fed-batch process (0.63 mol H/mol). Hydrogen produced from lignocellulose biomass is deemed as a promising fuel of the future. However, direct cellulose utilization remains an issue due to the low hydrogen yields. In this study, the long-term effect of inoculum (anaerobic sludge) heat pretreatment on hydrogen production from untreated cellulose and starch was evaluated during repeated batch processes. The inoculum pretreatment at 90°C was not sufficient to suppress H consuming bacteria, both for starch and cellulose. Although hydrogen was produced, it was rapidly utilized with simultaneous accumulation of acetic and propionic acid. The pretreatment at 100°C (20 min) resulted in the successful enrichment of hydrogen producers on starch. High production of hydrogen (1.2 l H/l) and H yield (1.7 mol H/mol) were maintained for 130 days, with butyric (1.5 g/l) and acetic acid (0.65 g/l) as main byproducts. On the other hand, the process with cellulose showed lower hydrogen production (0.3 l H/l) with simultaneous high acetic acid (1.4 g/l) and ethanol (1.2 g/l) concentration. Elimination of sulfates from the medium led to the efficient production of hydrogen in the initial cycles – 0.97 mol H/mol (5.93 mmol H/g). However, the effectiveness of pretreatment was only temporary for cellulose, because propionic acid accumulation (1.5 g/l) was observed after 25 days, which resulted in lower H production. The effective production of hydrogen from cellulose was also maintained for 40 days in a repeated fed-batch process (0.63 mol H/mol).
木质纤维素生物质产生的氢气被认为是未来一种很有前景的燃料。然而,由于氢气产率较低,直接利用纤维素仍然是一个问题。在本研究中,在重复批次过程中评估了接种物(厌氧污泥)热预处理对未处理纤维素和淀粉产氢的长期影响。90°C的接种物预处理不足以抑制淀粉和纤维素的耗氢细菌。虽然产生了氢气,但它很快被利用,同时积累了乙酸和丙酸。100°C(20分钟)的预处理成功地富集了淀粉上的产氢菌。氢气高产率(1.2升氢气/升)和氢气产率(1.7摩尔氢气/摩尔)维持了130天,主要副产物为丁酸(1.5克/升)和乙酸(0.65克/升)。另一方面,纤维素过程的产氢量较低(0.3升氢气/升),同时乙酸(1.4克/升)和乙醇(1.2克/升)浓度较高。从培养基中去除硫酸盐导致初始循环中氢气的高效产生——0.97摩尔氢气/摩尔(5.93毫摩尔氢气/克)。然而,预处理对纤维素的有效性只是暂时的,因为25天后观察到丙酸积累(1.5克/升),这导致氢气产量降低。在重复补料分批过程中,纤维素产氢的有效性也维持了40天(0.63摩尔氢气/摩尔)。木质纤维素生物质产生的氢气被认为是未来一种很有前景的燃料。然而,由于氢气产率较低
