Journal of Guangxi Normal University(Natural Science Edition) ›› 2024, Vol. 42 ›› Issue (6): 53-66.doi: 10.16088/j.issn.1001-6600.2024030604

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Current Status and Trends of Algal Coagulation Elimination Technology in Drinking Water Treatment: a Visual Analysis Based on CiteSpace

LIU Yang1,2*, ZHANG Yijie1,2, ZHANG Yan1,2, LI Ling3, KONG Xiangming3, LI Hong3   

  1. 1. Henan International Joint Laboratory of Aquatic Ecotoxicology and Health Protection (Henan Normal University), Xinxiang Henan 453007, China;
    2. College of Life Sciences, Henan Normal University, Xinxiang Henan 453007, China;
    3. Xinxiang Capital Water Service Co., Ltd., Water Quality Testing Center, Xinxiang Henan 453004, China
  • Received:2024-03-06 Revised:2024-05-22 Online:2024-12-30 Published:2024-12-30

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Abstract: Algae blooms in lake and reservoir caused by eutrophication has a potential impact on the drinking water treatment process. In order to accurately grasp the latest research and development trend in this field, CiteSpace bibliometrics software was used to analyze the literature on algal coagulation in drinking water from 1999 to 2023 in the core database of the China National Knowledge Infrastructure (CNKI) and Web of Science(WOS) in detail. The results showed that: ① Within the statistical interval, the total number and average number of published papers on algae coagulation in drinking water in the CNKI database were higher than those in the WOS database. Additionally, the number of published papers in both databases was observed to be stable and gradually increasing over time. ② The publication volume of high-yield authors in the CNKI database was significantly lower compared with high-yield authors in the WOS database. Additionally, the CNKI database have not established a high-yield core author group. ③ Publishing institutions in the WOS database primarily consist of universities and research institutes, with limited connections to local enterprises. On the other hand, the cooperation relationships among CNKI database publishing institutions showed clear regional affiliations, but their ability for cross-regional collaboration was weak, which may hinder the advancement of future research. ④ The research content of the two databases mainly includes drinking water, drinking water treatment, eutrophication, pre-oxidation, and disinfection by-products, with a different focus. The WOS database primarily concentrates on molecular-level research of cell metabolism, covering topics such as cell integrity, dissolved organic carbon, and moderate pre-oxidation. While the CNKI database focuses on physical and chemical algae removal technologies like membrane fouling, enhanced coagulation, chlorine dioxide, coagulation, and pre-oxidation. Combining the findings from both databases can enhance the theoretical framework in the field of drinking water coagulation and algae removal, thereby enriching the depth and breadth of the research. Although there was a wealth of practical experience and theoretical basis in the field of algae coagulation in drinking water, there are still shortcomings in the depth of research and cooperation. And integration, environmental protection and intelligence are the trend of future development.

Key words: drinking water, algae, coagulation, elimination, CiteSpace, research progress

CLC Number:  TU991.2
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