In situ carbon dioxide capture to co-produce 1,3-propanediol, biohydrogen and micro-nano calcium carbonate from crude glycerol by Clostridium butyricum.

Xiao-Li Wang, Jin-Jie Zhou, Sheng Liu, Ya-Qin Sun, Zhi-Long Xiu
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引用次数: 2

Abstract

Background: Climate change caused by greenhouse gas emission has become a global hot topic. Although biotechnology is considered as an environmentally friendly method to produce chemicals, almost all biochemicals face carbon dioxide emission from inevitable respiration and energy metabolism of most microorganisms. To cater for the broad prospect of biochemicals, bioprocess optimization of diverse valuable products is becoming increasingly important for environmental sustainability and cleaner production. Based on Ca(OH)2 as a CO2 capture agent and pH regulator, a bioprocess was proposed for co-production of 1,3-propanediol (1,3-PDO), biohydrogen and micro-nano CaCO3 by Clostridium butyricum DL07.

Results: In fed-batch fermentation, the maximum concentration of 1,3-PDO reached up to 88.6 g/L with an overall productivity of 5.54 g/L/h. This productivity is 31.9% higher than the highest value previously reports (4.20 g/L/h). In addition, the ratio of H2 to CO2 in exhaust gas showed a remarkable 152-fold increase in the 5 M Ca(OH)2 group compared to 5 M NaOH as the CO2 capture agent. Green hydrogen in exhaust gas ranged between 17.2% and 20.2%, with the remainder being N2 with negligible CO2 emissions. During CO2 capture in situ, micro-nano calcite particles of CaCO3 with sizes in the range of 300 nm to 20 µm were formed simultaneously. Moreover, when compared with 5M NaOH group, the concentrations of soluble salts and proteins in the fermentation broth of 5 M Ca(OH)2 group were notably reduced by 53.6% and 44.1%, respectively. The remarkable reduction of soluble salts and proteins would contribute to the separation of 1,3-PDO.

Conclusions: Ca(OH)2 was used as a CO2 capture agent and pH regulator in this study to promote the production of 1,3-PDO. Meanwhile, micro-nano CaCO3 and green H2 were co-produced. In addition, the soluble salts and proteins in the fermentation broth were significantly reduced.

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利用丁酸梭菌原位捕集二氧化碳,以粗甘油为原料协同生产1,3-丙二醇、生物氢和微纳米碳酸钙。
背景:温室气体排放引起的气候变化已经成为一个全球性的热点话题。虽然生物技术被认为是一种环境友好的生产化学品的方法,但几乎所有的生物化学品都面临二氧化碳的排放,这是大多数微生物不可避免的呼吸和能量代谢。为了适应生物化工的广阔前景,各种有价值产品的生物工艺优化对环境可持续性和清洁生产变得越来越重要。以Ca(OH)2作为CO2捕集剂和pH调节剂,提出了丁酸梭菌DL07协同生产1,3-丙二醇(1,3- pdo)、生物氢和微纳米CaCO3的生物工艺。结果:在分批补料发酵中,1,3- pdo最高浓度可达88.6 g/L,总产率为5.54 g/L/h。这一产量比之前报道的最高值(4.20 g/L/h)高出31.9%。此外,5 M Ca(OH)2组废气中H2与CO2的比值比5 M NaOH组显著提高了152倍。废气中的绿氢含量在17.2%到20.2%之间,其余为N2,二氧化碳排放量可以忽略不计。在CO2原位捕集过程中,CaCO3微纳方解石颗粒同时形成,粒径在300 nm ~ 20µm之间。此外,与5M NaOH组相比,5M Ca(OH)2组发酵液中可溶性盐和蛋白质的浓度分别显著降低53.6%和44.1%。可溶性盐和蛋白质的显著减少有助于1,3- pdo的分离。结论:在本研究中,Ca(OH)2作为CO2捕集剂和pH调节剂促进1,3- pdo的生成。同时,微纳CaCO3和绿色H2共制。发酵液中可溶性盐和蛋白质含量显著降低。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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