利用生物矿物形成过程从尿液中去除和回收营养物质。

ACS Sustainable Resource Management Pub Date : 2024-09-13 eCollection Date: 2024-09-26 DOI:10.1021/acssusresmgt.4c00025
Robert E Colston, Ajay Nair, Peter Vale, Francis Hassard, Tom Stephenson, Ana Soares
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引用次数: 0

摘要

从废物中获取养分是一项大有可为的举措,既能推动和实现水领域的循环经济,又能缓解全球矿物质肥料短缺的问题。尿液是城市污水的一小部分,其中含有大量的氮、正磷酸盐 (PO4-P) 和化学需氧量 (COD)。分离尿液有助于有针对性地回收养分、减少废气排放、提高污水处理厂的处理能力,还能利用被忽视的重要养分,如植物生长所必需的镁(Mg2+)和钾(K+)。研究了所选微生物(Brevibacterium antiquum、Bacillus pumilus、Halobacterium salinarum、Idiomarina loihiensis 和 Myxococcus xanthus)通过生物矿物形成的硬石膏从新鲜尿液中去除和回收营养物质的能力。在开放培养的新鲜尿液中,所选微生物与本地微生物竞争,完整细胞数是未接种对照组的 1.3 至 2.3 倍。培养 4 天后,PO4-P 的去除率达到 50%,当尿液中添加 Mg2+ 时,去除率达到 96%。此外,可溶性 COD 减少了 60%;对照组的尿素水解率仅小于 3%,但接种后 10 天的尿素水解率达到了 35%。回收沉淀物的主要形态是八面体和棱柱形,用能量色散光谱和 X 射线衍射法鉴定为硬石膏(即生物硬石膏),但 K+ 的含量也达到了 5%。每升尿液可回收多达 1 克生物硬石。这些结果表明,产生生物矿物质的微生物能够在尿液中成功生长,并回收生物硬泡石等营养物质,这些营养物质有可能被用作可持续肥料或化学品。
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Nutrient Removal and Recovery from Urine Using Bio-Mineral Formation Processes.

Harvesting nutrients from waste presents a promising initiative to advance and deliver the circular economy in the water sector while mitigating local shortages of mineral fertilizers worldwide. Urine, a small fraction of municipal wastewater, holds substantial amounts of nitrogen, orthophosphate (PO4-P), and chemical oxygen demand (COD). Separating urine aids targeted nutrient recovery, emissions reduction, and releasing capacity in wastewater treatment plants and taps into overlooked vital nutrients like magnesium (Mg2+) and potassium (K+), essential for plant growth. The ability of selected microorganisms (Brevibacterium antiquum, Bacillus pumilus, Halobacterium salinarum, Idiomarina loihiensis, and Myxococcus xanthus) to remove and recover nutrients from fresh urine through bio-mineral formation of struvite was investigated. The selected microorganisms outcompeted native microbes in open-culture fresh urine, and intact cell counts were 1.3 to 2.3 times larger than in noninoculated controls. PO4-P removal reached 50% after 4 days of incubation and 96% when urine was supplemented with Mg2+. Additionally, soluble COD was reduced by 60%; urea hydrolysis was only < 3% in controls, but it reached 35% in inoculated urine after 10 days. The dominant morphology of recovered precipitates was euhedral and prismatic, identified using energy dispersive spectroscopy and X-ray diffraction as struvite (i.e., bio-struvite), but K+ was also present at 5%. Up to 1 g bio-struvite/L urine was recovered. These results demonstrate the ability of bio-mineral producing microorganisms to successfully grow in urine and recover nutrients such as bio-struvite, that could potentially be used as sustainable fertilizers or chemicals.

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