Settlement ponds are used to treat aquaculture discharge water by removing nutrients through physical (settling) and biological (microbial transformation) processes. Nutrient removal through settling has been quantified, however, the occurrence of, and potential for microbial nitrogen (N) removal is largely unknown in these systems. Therefore, isotope tracer techniques were used to measure potential rates of denitrification and anaerobic ammonium oxidation (anammox) in the sediment of settlement ponds in tropical aquaculture systems. Dinitrogen gas (N2) was produced in all ponds, although potential rates were low (0–7.07 nmol N cm−3 h−1) relative to other aquatic systems. Denitrification was the main driver of N2 production, with anammox only detected in two of the four ponds. No correlations were detected between the measured sediment variables (total organic carbon, total nitrogen, iron, manganese, sulphur and phosphorous) and denitrification or anammox. Furthermore, denitrification was not carbon limited as the addition of particulate organic matter (paired t-Test; P = 0.350, n = 3) or methanol (paired t-Test; P = 0.744, n = 3) did not stimulate production of N2. A simple mass balance model showed that only 2.5% of added fixed N was removed in the studied settlement ponds through the denitrification and anammox processes. It is recommended that settlement ponds be used in conjunction with additional technologies (i.e. constructed wetlands or biological reactors) to enhance N2 production and N removal from aquaculture wastewater.
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机译:沉降池用于通过物理(沉降)和生物(微生物转化)过程去除养分来处理水产养殖废水。已经确定了通过沉降去除营养物的数量,但是,在这些系统中微生物氮(N)的发生和潜力尚不明确。因此,同位素示踪技术被用于测量热带水产养殖系统中沉降池沉积物中反硝化和厌氧铵氧化的潜在速率。与其他水生系统相比,所有池塘中都产生了氮气(N2),但潜在的发生率较低(0-7.07 nmol N cm -3 h -1 )。反硝化是N2产生的主要驱动力,只有四个池塘中的两个才发现了厌氧氨氧化。在测得的沉积物变量(总有机碳,总氮,铁,锰,硫和磷)与反硝化或厌氧氨氮之间未发现相关性。此外,反硝化不受碳的限制,因为添加颗粒有机物(配对t-试验; P = 0.350,n = 3)或甲醇(配对t-Test; P = 0.744,n = 3)不会刺激N2的产生。 。一个简单的质量平衡模型表明,在研究的沉降池中,通过反硝化和厌氧氨氧化工艺仅去除了2.5%的固定氮。建议将沉淀池与其他技术(即人工湿地或生物反应器)结合使用,以提高氮的生产量和水产养殖废水的氮去除率。
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