Bulletin of Chinese Academy of Sciences (Chinese Version)
Keywords
large lake; physical model; ecological simulation; ecological process; ecological restoration
Abstract
Lake is an important component of inland water resource of China, and key ecological component of Mountain-RiverForest-Farmland-Lake-Grassland life community. Lake is also a perfect research unit for ecological theory owing to its relative clearly isolate ecosystem. Field observatory, controlled experiment, and numerical simulation are common research methods for limnology theory development and ecological restoration technology innovation. In shallow lakes, the lake ecosystem is very sensitive to the change of environmental condition. For example, changes of physical condition, such as wind-wave, could strongly influence the sediment-water interaction, light condition of water, and the growth of phytoplankton, and finally change the whole ecosystem structure and ecological service. In China, field experiment facilities for limnology research are deficient. Most of the field experiments were undertook in small enclosures or small ponds. It is an urgent need of large-scale controlled field experiment system in limnology research. With the financial support of corner-stone research infrastructure project for the field station network of Chinese Academy of Sciences, Taihu Laboratory for Lake Ecosystem Research (TLLER) has accomplished a large-scale physical and ecological experimental infrastructure system, Shallow Lake Physical-Ecological Modeling Platform (LAMP) next to Lake Taihu, the third largest freshwater lake of China. The platform includes physical lake model, large ecological experimental field on lake, and 3-D numerical model of Lake Taihu (DYTHE). LAMP platform significantly enhances the research ability of controlled physical and ecological experiment about limnology theory and technology development.
First page
1098
Last Page
1107
Language
Chinese
Publisher
Bulletin of Chinese Academy of Sciences
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Recommended Citation
ZHU, Guangwei; WEI, Hongwei; YANG, Tingfeng; LI, Wei; LI, Kuanyi; SHEN, Ruijie; MIN, Shen; DENG, Jiangming; and QIN, Boqiang
(2021)
"Shallow Lake Physical-ecological Process Modeling Platform (LAMP),"
Bulletin of Chinese Academy of Sciences (Chinese Version): Vol. 36
:
Iss.
9
, Article 15.
DOI: https://doi.org/10.16418/j.issn.1000-3045.20210822001
Available at:
https://bulletinofcas.researchcommons.org/journal/vol36/iss9/15