Photofermentative hydrogen production by immobilized Rhodopseudomonas sp. S16-VOGS3 cells in photobioreactors

Energy Reviews Pub Date : 2023-11-08 DOI:10.1016/j.enrev.2023.100055

Isabela C. Moia , Aikaterini Kanaropoulou , Demetrios F. Ghanotakis , Pietro Carlozzi , Eleftherios Touloupakis

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Abstract

One of the most important solutions to overcome energy and environmental problems and to replace the fossil fuel-based economy could be the use of photosynthetic microorganisms. The use of photosynthetic microorganisms is a potential alternative to energy generation from fossil fuels because they efficiently produce hydrogen (H₂). Immobilization of photosynthetic microorganisms is used for many biotechnological applications such as H₂ production. This method appears attractive because it restricts cell movement in an entrapped matrix. Immobilization of Rhodopseudomonas sp. S16-VOGS3 cells is a promising way to improve H₂ production. In this work, the ability of immobilized Rhodopseudomonas sp. S16-VOGS3 cells to produce H₂ was investigated in two types of PBRs. The PBRs used in this work were a cylindrical one with 0.2 L working volume (C-PBR) and a flat Roux type with 0.6 L working volume (FRT-PBR). The calcium alginate beads prepared were resistant to culture mixing and showed little leakage of cells, and the immobilized cells continued the photofermentation process in both PBRs. The immobilized cells in the C-PBR produced 936.8 mL of H₂ with an average H₂ production rate of 2.99 mL/h. The average productivity was 126.4 μL (H₂)/mg (cells)/h or 14.96 mL (H₂)/L (culture)/h, and the light conversion efficiency was 2.37 %. The immobilized cells in the FRT-PBR produced a total of 662.2 mL of H₂ with an average H₂ production rate of 1.55 mL/h. The average productivity was 31.1 μL (H₂)/mg (cells)/h or 2.58 mL (H₂)/L (culture)/h, and the light conversion efficiency was 0.52 %. The more uniform and therefore more efficient degree of bacterial cell mixing achieved in the C-PBR with cylindrical configuration played an important role compared to the FRT-PBR. In the FRT-PBR, the beads were aggregated at the bottom, which limited light penetration and resulted in low H₂ production efficiency.

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固定化红假单胞菌sp. S16-VOGS3细胞在光生物反应器中的光发酵产氢

克服能源和环境问题并取代以化石燃料为基础的经济的最重要解决方案之一可能是利用光合微生物。光合微生物的使用是化石燃料发电的潜在替代品，因为它们能有效地产生氢(H2)。固定化光合微生物用于许多生物技术应用，如制氢。这种方法看起来很有吸引力，因为它限制了细胞在捕获矩阵中的运动。固定化Rhodopseudomonas sp. S16-VOGS3细胞是一种很有前途的提高H2产量的方法。在这项工作中，研究了固定化红假单胞菌sp. S16-VOGS3细胞在两种pbr中产生H2的能力。本研究使用的pbr为工作容积为0.2 L的圆柱形pbr (C-PBR)和工作容积为0.6 L的扁平Roux型(FRT-PBR)。制备的海藻酸钙微球抗混合培养，细胞渗漏少，固定化后的细胞在两种pbr中都能继续光发酵过程。固定化细胞在C-PBR中产氢936.8 mL，平均产氢速率为2.99 mL/h。平均产率为126.4 μL (H2)/mg(细胞)/h或14.96 mL (H2)/L(培养物)/h，光转化效率为2.37%。固定化细胞在FRT-PBR中共产H2 662.2 mL，平均产氢速率为1.55 mL/h。平均产率为31.1 μL (H2)/mg(细胞)/h或2.58 mL (H2)/L(培养物)/h，光转换效率为0.52%。与FRT-PBR相比，圆柱形结构的C-PBR更均匀，因此更有效地实现了细菌细胞混合程度。在FRT-PBR中，微球聚集在底部，这限制了光的穿透，导致产氢效率低。

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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来源期刊

Energy Reviews

CiteScore

7.90

自引率

0.00%

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