Research

Publications
Title: Sediment diffusion is feasible to simultaneously reduce nitrate discharge from recirculating aquaculture system and ammonium release from sediments in receiving intensive aquaculture pond
First author: Jia, Zhiming; Wang, Jie; Liu, Xueyu; Yan, Zuting; Bai, Xuelan; Zhou, Xiaodi; He, Xugang; Hou, Jie
Journal: SCIENCE OF THE TOTAL ENVIRONMENT
Years: 2023
Volume / issue: /
DOI: 10.1016/j.scitotenv.2022.160017
Abstract: Nitrogen accumulation has become one of the greatest unresolved challenges restricting the development of aquaculture worldwide. In recirculating aquaculture system (RAS), lack of organic matter (OM) and sensitive organisms makes it dif-ficult to apply efficient denitrifying technology, thus leading to a high nitrate-nitrogen (NO3--N) accumulation. In contrast, excess OM accumulation in intensive aquaculture pond sediments is associated with dissolved oxygen depletion and ammonium-nitrogen (NH4+-N) accumulation in the sediments. Based on the opposing effects of OM on the nitrogen accu-mulation in RAS and intensive aquaculture ponds, this study assessed the feasibility of simultaneously reducing NO3--N discharge from RAS and controlling NH4+-N accumulation in intensive aquaculture ponds by in situ diffusing RAS tailwa-ter containing NO3--N into intensive aquaculture pond sediments. The results showed that NO3--N diffusion strategy im-proved the native sediment denitrification capacity, thus increasing NO3--N removal efficiency from RAS tailwater and significantly decreasing the NH4+-N concentration in interstitial water and the total organic carbon content in intensive aquaculture pond sediments. High-throughput sequencing and quantitative real-time polymerase chain reaction (qPCR) results revealed that NO3--N addition significantly increased both nitrifying bacteria and denitrifying bacteria abundance. These results implied that NO3--N diffusion strategy could effectively stimulate microbial decomposition of OM, thus re-lieving the hypoxia limitation of sediment nitrification. Overall, this study offers a feasible method for simultaneous reduc-tion of NO3--N from RAS tailwater and NH4+-N in intensive aquaculture ponds with low cost and high efficiency.