Nontraditional biomanipulation: A powerful ecotechnology to combat cyanobacterial blooms in eutrophic freshwaters

Chen, Jun; Liu, Jiarui; Han, Shengpan; Su, Haojie; Xia, Wulai; Wang, Haijun; Liu, Yong; Zhang, Liang; Ke, Zhixin; Zhang, Xia; Tang, Huijuan; Shen, Hong; Tao, Min; Shi, Pengling; Zhang, Weizhen; Wang, Huan; Zhang, Jia; Chen, Yuru; Rao, Qingyang; Rao, Xiao; Xie, Liqiang; Chen, Feizhou; Deng, Xuwei; Fan, Xiaoyue; He, Jun; Chen, Liang; Xu, Jun; Xie, Ping

doi:10.59717/j.xinn-life.2023.100038

Cited by 39 publications

(2 citation statements)

References 122 publications

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“…Global biodiversity loss in freshwater ecosystems has increased during the past decades due to the intensification of human activities such as land use change, environmental pollution, species invasion, and climate changes. [8][9][10][11] As species diversity has been widely recognized to play a major role in influencing ecosystem functioning and stability, 12,13 ecologists generally support the positive biodiversity-stability relationship, where higher species diversity is expected to buffer the risk of ecosystem collapse. 14,15 Nonetheless, this idea was challenged by the modeling work of May, who found that species diversity has negative relationships with ecosystem stability.…”

Section: Introductionmentioning

confidence: 99%

No positive effects of biodiversity on ecological resilience of lake ecosystems

Su,

Li,

Zhong

et al. 2024

TIG

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<p>Ecological resilience is critical for ecosystems to persist in the face of perturbations without shifting to a different state. Global biodiversity loss in multiple ecosystems is considered to be associated with decreasing ecological resilience and increasing the risk of ecosystem collapse. However, how temporal changes in biodiversity affect ecological resilience in natural ecosystems remains poorly elucidated. By analyzing subfossil records of diatoms, chironomids, and cladocerans from 53 lake sediment cores across the globe, we found that species richness showed an increasing trend with time, while beta diversity and ecological resilience presented a decreasing temporal trend when ecosystems are approaching the abrupt shift. Asynchronous fluctuations among species and temporal stability at species level are suggested to be the mechanisms that contribute to the maintenance of temporal community stability. We found species richness and beta diversity have positive effects on species asynchrony but negative effects on species stability. However, we found that species asynchrony and species stability had negative relationships with ecological resilience, with species richness and beta diversity overall having no positive effects on ecological resilience. We highlighted that biodiversity effects on ecological resilience are not only the role of species richness, but also the species assemblage and network complexity of species-species interactions. Our study indicates that increased species diversity and community heterogeneity may be not beneficial for the ecosystem to recover from disturbances at a lake ecosystem scale, which has great implications for the assessment of ecological resilience and predicting ecosystem collapse in future global environmental change scenarios.</p>

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Section: Introductionmentioning

confidence: 99%

No positive effects of biodiversity on ecological resilience of lake ecosystems

Su,

Li,

Zhong

et al. 2024

TIG

Self Cite

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“…Physical and chemical control methods play a role in many specific environments, but most of them are costly, inefficient, and ecologically damaging compared to biological control methods. Biological methods include aquatic plant management, biological filter feeding, algae management, and microbiological management [19][20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Automatic Group Decision-Making for Algal Bloom Management Based on Information Self-Learning

Bai,

Niu,

Zhao

et al. 2024

Water

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The phenomenon of algal bloom seriously affects the function of the aquatic ecosystems, damages the landscape of urban river and lakes, and threatens the safety of water use. The introduction of a multi-attribute decision-making method avoids the shortcomings of traditional algal bloom management that relies on manual experience. However, the weight-calculation part of this method still receives the artificial influence of human factors, which reduces the accuracy and scientific rigor of the decision. This paper presents a group decision-making method based on information self-learning which makes decision weights automatically clustered and assigned. A general framework of decision-making management is constructed for the algal bloom management process. In the decision-making process, an improved density-based clustering algorithm is used to automatically cluster and rank the decision data in the form of the three-parameter interval number, and ultimately obtain the optimal management method that meets the management objectives. Finally, the method was applied at the monitoring station of Sanjiadian Reservoir in Beijing, China. Based on the treatment objectives and water quality monitoring data of the station, relevant experts were invited to evaluate the management solutions, and the information self-organizing algorithm of this paper was used to automatically rank the decision-making methods, and finally obtain the most suitable management method for the station. Comparison with the water quality data and treatment inputs after the previous man-made selection of treatment options, and discussion among experts, show that the decision-making method is feasible and effective, and contributes to the sustainable treatment of algal blooms.

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