News Release

An efficient technique for the remediation of eutrophic lakes

Peer-Reviewed Publication

KeAi Communications Co., Ltd.

Mechanism diagram of synergistic effect of vermiculite and submerged plants

image: The content of total phosphorus (sum of the OP and IP) in the lying water and the DGT-P distributed on the surface of the sediment significantly decreased by the vermiculite addition, especially in the 5% vermiculite + Vallisneria spiralis group and 10% vermiculite + Vallisneria spiralis group. view more 

Credit: Rou Wang

When the amount of nutrients from outside sources is reduced, the release of nutrients already present in the water becomes the main reason for water pollution due to excessive growth of plants and algae. To restore and maintain a healthy balance in lakes affected by this pollution, scientists are focusing on using special mineral-based materials and techniques that involve planting underwater vegetation. These methods have gained popularity as they help promote the long-term recovery of these ecosystems.

Vermiculite is a natural mineral with a unique structure that can absorb nutrients like nitrogen and phosphorus, as well as harmful pollutants like heavy metals. It can also help improve the physical makeup of sediment. However, little is known about how sediment is affected when using vermiculite alongside underwater plants.

To address the knowledge gap, a group of researchers from China conducted a study to investigate the impact of combining vermiculite with two types of submerged plants, Vallisneria spiralis and Hydrilla verticillate, on the properties of lake sediment and the structure of the microbial community (Figure 1).

“We found that the concentration of total phosphorus (TP) in the water above the sediment decreased significantly by 63.29%–91.17% when vermiculite was used,” shared Rou Wang, first author of the study. “Vermiculite may help in controling the release of unstable phosphorus and enhances the absorption of nutrients by plant roots.”

Additionally, the vermiculite-treated sediment showed significantly lower levels of unstable sulfur compared to the control group, indicating that vermiculite can reduce sulfur toxicity for submerged plants.

“Throughout the experiment, the pH of the sediment in all treatment groups remained neutral. However, the oxygen reduction potential (ORP) in the vermiculite-treated group was significantly higher, particularly in the sediment layer between 3 to 6 centimeters,” added Wang. “Moreover, the amount of vermiculite added had a positive correlation with sediment pH, ORP, and dissolved oxygen (DO) in the water. These finding suggest that the porous nature of vermiculite enhances sediment permeability and improves oxygen circulation.”

Further, the analysis of sediment microbes revealed that the abundance of microorganisms in the 10% vermiculite + Vallisneria spiralis group and 50% vermiculite + Hydrilla verticillate group was 1.67 times and 3.50 times higher, respectively, compared to the control group. Also, the relative abundance of beneficial bacteria, such as Acidobacteria and Proteobacteria, increased significantly and showed a positive correlation with the proportion of vermiculite used, indicating that vermiculite promotes the growth of beneficial microorganisms.

The team's comprehensive findings have been published in the KeAi journal Water Biology and Security.

 The combined remediation technology of vermiculite and submerged plants effectively improved water quality and sediment properties, thus providing a theoretical reference for its application in lake ecological restoration engineering.

“The combination of vermiculite and submerged plants has proven to be an effective remediation technology that enhances water quality and sediment properties. Our study serves as a valuable theoretical reference for the application of this approach in lake ecological restoration projects,” concluded co-corresponding author Yi Zhang.

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Contact the author: Qiaohong Zhou, Yi Zhang. Institute of Hydrobiology, Chinese Academy of Sciences, qhzhou@ihb.ac.cn; zhangyi@ihb.ac.cn.

The publisher KeAi was established by Elsevier and China Science Publishing & Media Ltd to unfold quality research globally. In 2013, our focus shifted to open access publishing. We now proudly publish more than 100 world-class, open access, English language journals, spanning all scientific disciplines. Many of these are titles we publish in partnership with prestigious societies and academic institutions, such as the National Natural Science Foundation of China (NSFC).

 


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