Abdul Mannan Zafar , Hasan Al Mosteka , Ashraf Aly Hassan
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For Cl</span><sup>−</sup> ion, the highest elimination capacity on day 15 was measured to 18.1 g.m<sup>−3</sup>.hr<sup>−1</sup> for <em>C. reinhardtii</em> (1:1), the highest among all the studied strains and ratios. Among all the strains, the highest chlorophyll content of 234 ± 0.43 mg·L<sup>−1</sup> was measured for <em>Trichormus variabilis</em><span> (1:1) on the 15th day, and cell leaching was measured by flow cytometer analysis with ∼6.14 × 10</span><sup>8</sup> cells·mL<sup>−1</sup><span> were released from the beads. In oxygen microsensor tests, oxygen content decreased as depth was increased, indicating that growth occurred closer to the surface. Immobilization increased algae's salt tolerance capacity, resulting in the prolonged cellular life span. Biomass harvesting is not required if the algae can be consumed in the immobilization technique. 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引用次数: 1
摘要
本研究首次以四种不同的微藻菌株(绿藻、莱茵衣藻、变异毛藻和斜角藻)在真实海水中固定化进行生物脱盐。将固定化微球按1:1、1:2和1:3(生物质与海藻酸钠)的比例直接施用于真实海水中。连续15天测定氯离子的还原量。其他参数包括pH、叶绿素、绝对细胞数和氧微传感器。对Cl -离子,第15天的最大消除量为18.1 g m−3。hr−1以莱因哈德梭菌(1:1)最高。在所有菌株中,变异毛霉(1:1)的叶绿素含量在第15天最高,为234±0.43 mg·L−1,流式细胞仪检测细胞浸出,从珠中释放约6.14 × 108个细胞·mL−1。在氧微传感器测试中,氧含量随着深度的增加而下降,表明生长发生在靠近表面的地方。固定化提高了藻类的耐盐能力,延长了细胞寿命。如果藻类可以在固定化技术中被消耗,则不需要生物质收获。介绍了一种固定化处理方法对脱盐效果的影响。
Performance of immobilized microalgal strains for biodesalination of real seawater
In this study, biodesalination was performed using four different microalgal strains (Euglena deses, Chlamydomonas reinhardtii, Trichormus variabilis, and Scenedesmus obliquus) in real seawater for the first time in immobilized method. Immobilized beads in the ratio of 1:1, 1:2, and 1:3 (biomass to sodium alginate), were applied directly to real seawater in nutrient-deprivation conditions. The chloride ion reduction was measured for 15 days continuously. The other parameters investigated were pH, chlorophyll, absolute cell count, and oxygen microsensor. For Cl− ion, the highest elimination capacity on day 15 was measured to 18.1 g.m−3.hr−1 for C. reinhardtii (1:1), the highest among all the studied strains and ratios. Among all the strains, the highest chlorophyll content of 234 ± 0.43 mg·L−1 was measured for Trichormus variabilis (1:1) on the 15th day, and cell leaching was measured by flow cytometer analysis with ∼6.14 × 108 cells·mL−1 were released from the beads. In oxygen microsensor tests, oxygen content decreased as depth was increased, indicating that growth occurred closer to the surface. Immobilization increased algae's salt tolerance capacity, resulting in the prolonged cellular life span. Biomass harvesting is not required if the algae can be consumed in the immobilization technique. The performance of biodesalination using an immobilized treatment method with more efficient salt-removing microalgal strain is recommended.
期刊介绍:
Desalination is a scholarly journal that focuses on the field of desalination materials, processes, and associated technologies. It encompasses a wide range of disciplines and aims to publish exceptional papers in this area.
The journal invites submissions that explicitly revolve around water desalting and its applications to various sources such as seawater, groundwater, and wastewater. It particularly encourages research on diverse desalination methods including thermal, membrane, sorption, and hybrid processes.
By providing a platform for innovative studies, Desalination aims to advance the understanding and development of desalination technologies, promoting sustainable solutions for water scarcity challenges.
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