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氧纳米气泡制备及其在农业领域的应用研究进展

张羽嘉 徐书含 李德天 串丽敏 朱元宏 王丰 曹林奎 沙之敏

张羽嘉, 徐书含, 李德天, 串丽敏, 朱元宏, 王丰, 曹林奎, 沙之敏. 氧纳米气泡制备及其在农业领域的应用研究进展[J]. 中国生态农业学报 (中英文), 2023, 31(11): 1780−1791 doi: 10.12357/cjea.20230066
引用本文: 张羽嘉, 徐书含, 李德天, 串丽敏, 朱元宏, 王丰, 曹林奎, 沙之敏. 氧纳米气泡制备及其在农业领域的应用研究进展[J]. 中国生态农业学报 (中英文), 2023, 31(11): 1780−1791 doi: 10.12357/cjea.20230066
ZHANG Y J, XU S H, LI D T, CHUAN L M, ZHU Y H, WANG F, CAO L K, SHA Z M. Progress in research on preparation and application of oxygen nanobubbles in agriculture[J]. Chinese Journal of Eco-Agriculture, 2023, 31(11): 1780−1791 doi: 10.12357/cjea.20230066
Citation: ZHANG Y J, XU S H, LI D T, CHUAN L M, ZHU Y H, WANG F, CAO L K, SHA Z M. Progress in research on preparation and application of oxygen nanobubbles in agriculture[J]. Chinese Journal of Eco-Agriculture, 2023, 31(11): 1780−1791 doi: 10.12357/cjea.20230066

氧纳米气泡制备及其在农业领域的应用研究进展

doi: 10.12357/cjea.20230066
基金项目: 上海市水稻产业体系项目(202203)资助
详细信息
    作者简介:

    张羽嘉, 主要研究方向为农业资源与环境。E-mail: yjzhang09@126.com

    通讯作者:

    沙之敏, 主要研究方向为植物营养学与农业面源污染控制研究。E-mail: zhiminsha@sjtu.edu.cn

  • 中图分类号: S-2; X-1

Progress in research on preparation and application of oxygen nanobubbles in agriculture

Funds: This study was supported by the Agriculture Research System of Shanghai, China (202203).
More Information
  • 摘要: 为系统了解氧纳米气泡及其在农业领域的应用研究进展与发展趋势, 本文就近15年来氧纳米气泡的研究进展与成果, 总结了氧纳米气泡的研究概况; 对氧纳米气泡的制备方法与性质进行了探讨; 重点综述了氧纳米气泡在农业生产领域与农业环境治理领域的应用。农业生产领域的应用包括促进种子发育与作物生长、提高水产养殖产量与经济效益等, 农业环境治理领域的应用, 包括促进稻田甲烷减排、去除土壤中的重金属等污染物质、治理农业面源污染等。展望了氧纳米气泡技术今后的研究重点与对策建议, 包括深入研究氧纳米气泡的增氧机理及作用机制, 进一步开发农业领域氧纳米气泡的制备技术, 拓展氧纳米气泡技术在农业生产及环境修复中的适用性, 开展氧纳米气泡的规模化应用研究等。研究成果可为氧纳米气泡的基础研究和在农业领域的应用研究提供思路与方法。
  • 图  1  1998—2022年纳米气泡与氧纳米气泡主题发文数量

    Figure  1.  Quantity of publications on nanobubble and oxygen nanobubble from 1998 to 2022

    图  2  2002—2022年氧纳米气泡主题研究热点分布

    圆圈的大小代表关键词出现的频次, 出现频次越高, 圆圈越大。不同颜色代表不同的聚类, 图2中共有5个聚类, 连线代表两者间相互联系。The size of the circle represents the frequency of keywords. The higher the frequency, the larger the circle. Different colors represent different clusters. There are 5 clusters in Figure 2, and the connecting lines represent the relationship between them.

    Figure  2.  Hot spots distribution of oxygen nanobubble theme research from 2002 to 2022

    图  3  氧纳米气泡在农业领域中的应用

    Figure  3.  Application of oxygen nanobubbles in the agriculture

    图  4  氧纳米气泡对作物栽培的影响机理

    Figure  4.  Impact mechanism of oxygen nanobubbles on crop cultivation

    图  5  氧纳米气泡对稻田甲烷减排与土壤重金属污染治理的影响机理

    Figure  5.  Impact mechanism of oxygen nanobubbles on methane emission reduction in rice fields and soil heavy metal pollution control

    图  6  氧纳米气泡对农业面源污染治理的影响机理

    Figure  6.  Impact mechanism of oxygen nanobubbles on agricultural non-point source pollution control

    表  1  氧纳米气泡性质检测方法及特点

    Table  1.   Characteristics of different methods for detecting the properties of oxygen nanobubble

    检测方法
    Test method
    特点
    Characteristic
    文献
    Literature
    动态光散射技术
    Dynamic light scattering
    用于测量体相氧纳米气泡尺寸和粒径分布, 但由于测的是平均值, 所以数据重复性较差
    It is used to measure the size and particle size distribution of bulk oxygen nanobubbles, but the data repeatability is poor due to its measurement of the average value
    [31]
    纳米颗粒追踪技术
    Nanoparticle tracking analysis
    改善了动态光散射技术的缺陷, 对体相氧纳米气泡的粒径分布进行更精准的分析, 但无法给出化学信息, 因此往往需要设计对照试验来提高准确性
    It improves the defect of dynamic light scattering technology and makes more accurate analysis on the particle size distribution of bulk oxygen nanobubbles, but the chemical information is not available, which needs contrast tests to improve the accuracy
    [32]
    共振质量测量法
    Resonant mass measurement
    用于测量体相纳米气泡的质量, 同时可以区分纳米颗粒与体相纳米气泡
    It is used to measure the mass of bulk nanobubbles and distinguish between nanoparticles and bulk nanobubbles
    [33]
    原子力显微镜
    Atomic force microscope
    可以定量观察高度、样貌分布与界面氧纳米气泡在扰动下的变化, 但无法提供气泡化学信息
    It can quantitatively observe nanobubbles’ height, appearance distribution, and the changes of interface oxygen nanobubbles under disturbance, but can not provide bubble’s chemical information
    [34]
    光学显微镜
    Optical microscope
    种类丰富, 下属的荧光显微镜常被用于观测界面氧纳米气泡
    It has a wide variety of types, of which fluorescence microscope is often used to observe interface oxygen nanobubbles
    [35]
    电子显微镜
    Electron microscope
    相比光学显微镜分辨率更高, 但对真空度等要求较高, 成像难度大, 体相氧纳米气泡与界面氧纳米气泡的检测均可应用
    Compared to optical microscope, it has higher resolution, but higher requirements for vacuum degree, which increases the imaging difficulty. It can be applied in the detection of both bulk oxygen nanobubbles and interface oxygen nanobubbles
    [36]
    电化学方法
    Electrochemical method
    追踪气泡形态变化较灵敏, 将电化学信号与经典成核理论相结合, 可计算电极表面氧纳米气泡的成核临界尺寸、接触角等, 但群体气泡不好观察
    It is sensitive in tracking changes in bubble morphology. Combining the electrochemical signal with the classical nucleation theory can calculate the nucleation critical size and contact angle of oxygen nanobubbles on the electrode surface, but it doesn’t suit for the observation of group bubbles
    [37]
    同步辐射X射线
    Synchrotron radiation X-ray
    可获取单个界面氧纳米气泡的化学组成信息与内部气体密度
    It can obtain the chemical composition information and internal gas density of single interface oxygen nanobubble
    [38]
    下载: 导出CSV
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  • 收稿日期:  2023-02-13
  • 录用日期:  2023-05-29
  • 网络出版日期:  2023-07-13
  • 刊出日期:  2023-11-10

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