Experimental application of micro/nano bubbles to control P release and separate P particles from benthic lake sediment

IF 3.5 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Journal of contaminant hydrology Pub Date : 2024-11-17 DOI:10.1016/j.jconhyd.2024.104466

Yong-Ho Choi , Yong-Hoon Jeong , Hong-Hue Thi Nguyen , Dong-Heui Kwak

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引用次数: 0

Abstract

Under persistent hypoxic conditions in the bottom layer of a lake, phosphorus (P) can be released from benthic sediments, significantly impacting the lake ecosystem. Hypoxia reduces iron ions, leading to P release through biogeochemical reactions associated with organic matter degradation, which in turn depletes dissolved oxygen (DO) in the sediment. The application of bubble technology is beneficial, as microbubbles (MBs) effectively remove P and enhance DO levels in both the overlying water and sediment surface. To identify the optimal bubble size for application, we conducted a series of flotation experiments and P fractionation studies using MBs and nanobubbles (NBs). Results indicate that NBs achieved a flotation efficiency of 12 %, MBs reached 44 %, and the combined use of NBs and MBs attained the highest flotation efficiency at 62 %, confirming that a combination of bubble sizes can enhance flotation efficiency. Furthermore, the introduction of air bubbles to mitigate hypoxia in the overlying water increased DO concentrations from 1 to 5 mg/L, followed by a gradual decline. P release in the bubble-injected groups was up to three times lower than in the control group. Water quality profiling of P distribution in sediments revealed a significant increase of approximately 10 % in iron-bound P under aerobic conditions, highlighting its critical role in regulating P release. Our findings suggest that utilizing a combination of bubble sizes, including NBs, enhances P removal efficiency and improves the anaerobic conditions of the lake's bottom layer, thereby further reducing P release from sediments.

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实验应用微/纳米气泡控制 P 释放并分离湖底沉积物中的 P 颗粒。

在湖泊底层持续缺氧的条件下，磷（P）会从底栖沉积物中释放出来，对湖泊生态系统产生重大影响。缺氧会减少铁离子，导致磷通过与有机物降解相关的生物地球化学反应释放出来，进而消耗沉积物中的溶解氧（DO）。气泡技术的应用是有益的，因为微气泡（MBs）能有效去除 P 并提高上覆水体和沉积物表面的溶解氧水平。为了确定应用的最佳气泡尺寸，我们使用微气泡和纳米气泡（NBs）进行了一系列浮选实验和 P 分馏研究。结果表明，NBs 的浮选效率为 12%，MBs 为 44%，而结合使用 NBs 和 MBs 的浮选效率最高，达到 62%，这证实了气泡大小的组合可提高浮选效率。此外，通过引入气泡来缓解上层水的缺氧状况，溶解氧浓度从 1 毫克/升上升到 5 毫克/升，随后逐渐下降。气泡注入组的 P 释放量是对照组的三倍。沉积物中 P 分布的水质剖面图显示，在有氧条件下，铁结合的 P 显著增加了约 10%，突出了其在调节 P 释放中的关键作用。我们的研究结果表明，利用包括 NBs 在内的多种气泡尺寸组合可提高对 P 的去除效率，改善湖泊底层的厌氧条件，从而进一步减少沉积物中 P 的释放。

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

Journal of contaminant hydrology 环境科学-地球科学综合

CiteScore

6.80

自引率

2.80%

发文量

129

审稿时长

68 days

期刊介绍： The Journal of Contaminant Hydrology is an international journal publishing scientific articles pertaining to the contamination of subsurface water resources. Emphasis is placed on investigations of the physical, chemical, and biological processes influencing the behavior and fate of organic and inorganic contaminants in the unsaturated (vadose) and saturated (groundwater) zones, as well as at groundwater-surface water interfaces. The ecological impacts of contaminants transported both from and to aquifers are of interest. Articles on contamination of surface water only, without a link to groundwater, are out of the scope. Broad latitude is allowed in identifying contaminants of interest, and include legacy and emerging pollutants, nutrients, nanoparticles, pathogenic microorganisms (e.g., bacteria, viruses, protozoa), microplastics, and various constituents associated with energy production (e.g., methane, carbon dioxide, hydrogen sulfide). The journal''s scope embraces a wide range of topics including: experimental investigations of contaminant sorption, diffusion, transformation, volatilization and transport in the surface and subsurface; characterization of soil and aquifer properties only as they influence contaminant behavior; development and testing of mathematical models of contaminant behaviour; innovative techniques for restoration of contaminated sites; development of new tools or techniques for monitoring the extent of soil and groundwater contamination; transformation of contaminants in the hyporheic zone; effects of contaminants traversing the hyporheic zone on surface water and groundwater ecosystems; subsurface carbon sequestration and/or turnover; and migration of fluids associated with energy production into groundwater.