Cyanobacterial blooms are one of the major threats to the health of aquatic ecosystems,and are increasing globally due to the synergistic eff ects of human activities and global climate change.The 7^(th) National Cyan...Cyanobacterial blooms are one of the major threats to the health of aquatic ecosystems,and are increasing globally due to the synergistic eff ects of human activities and global climate change.The 7^(th) National Cyanobacteria Bloom Forum was successfully held in May 28-30,2021 in Guiyang,Guizhou Province,China.The forum established a platform for exchanging views on the concerns of cyanobacterial blooms from Chinese researchers,lake managers,and treatment engineers.This special issue,“Cyanobacterial blooms in China:ecology,toxicity,and treatment”in Journal of Oceanography and Limnology,presents a collection of 14 papers on the physiological features and the infl uence on their concurrent aquatic biology of diff erent cyanobacterial groups.展开更多
Ongoing wind energy developments play a key role in mitigating the global effects of climate change and the energy crisis;however,they have complex ecological consequences for many flying animals.The Yellow Sea coast ...Ongoing wind energy developments play a key role in mitigating the global effects of climate change and the energy crisis;however,they have complex ecological consequences for many flying animals.The Yellow Sea coast is considered as an ecological bottleneck for migratory waterbirds along the East Asian–Australasian flyway(EAAF),and is also an important wind farm base in China.However,the effects of large-scale onshore wind farms along the EAAF on multidimensional waterbird diversity,and how to mitigate these effects,remain unclear.Here we examined how wind farms and their surrounding landscapes affected multidimensional waterbird diversity along the Yellow Sea coast.Taxonomic,functional,and phylogenetic diversity of the waterbird assemblages,and mean pairwise distances and nearest taxon distances with null models were quantified in relation to 4 different wind turbine densities.We also measured 6 landscape variables.Multi-dimensional waterbird diversity(taxonomic,functional,and phylogenetic diversity)significantly decreased with increasing wind turbine density.Functional and phylogenetic structures tended to be clustered in waterbird communities,and environmental filtering drove waterbird community assemblages.Furthermore,waterbird diversity was regulated by a combination of wind turbine density and landscape variables,with edge density of aquaculture ponds,in addition to wind turbine density,having the greatest independent contribution to waterbird diversity.These results suggest that attempts to mitigate the impact of wind farms on waterbird diversity could involve the landscape transformation of wind farm regions,for example,by including high-edge-density aquaculture ponds(i.e.,industrial ponds)around wind farms,instead of traditional low-edge-density aquaculture ponds.展开更多
Coastal blue carbon refers to the carbon taken from atmospheric CO2; fixed by advanced plants(including salt marsh,mangrove, and seagrass), phytoplankton, macroalgae, and marine calcifiers via the interaction of plant...Coastal blue carbon refers to the carbon taken from atmospheric CO2; fixed by advanced plants(including salt marsh,mangrove, and seagrass), phytoplankton, macroalgae, and marine calcifiers via the interaction of plants and microbes; and stored in nearshore sediments and soils; as well as the carbon transported from the coast to the ocean and ocean floor. The carbon sequestration capacity per unit area of coastal blue carbon is far greater than that of the terrestrial carbon pool. The mechanisms and controls of the carbon sink from salt marshes, mangroves, seagrasses, the aquaculture of shellfish and macroalgae, and the microbial carbon pump need to be further studied. The methods to quantify coastal blue carbon include carbon flux measurements, carbon pool measurements, manipulative experiments, and modeling. Restoring, conserving, and enhancing blue carbon will increase carbon sinks and produce carbon credits, which could be traded on the carbon market. The need to tackle climate change and implement China's commitment to cut carbon emissions requires us to improve studies on coastal blue carbon science and policy. The knowledge learned from coastal blue carbon improves the conservation and restoration of salt marshes,mangroves, and seagrasses; enhances the function of the microbial carbon pump; and promotes sustainable aquaculture, such as ocean ranching.展开更多
文摘Cyanobacterial blooms are one of the major threats to the health of aquatic ecosystems,and are increasing globally due to the synergistic eff ects of human activities and global climate change.The 7^(th) National Cyanobacteria Bloom Forum was successfully held in May 28-30,2021 in Guiyang,Guizhou Province,China.The forum established a platform for exchanging views on the concerns of cyanobacterial blooms from Chinese researchers,lake managers,and treatment engineers.This special issue,“Cyanobacterial blooms in China:ecology,toxicity,and treatment”in Journal of Oceanography and Limnology,presents a collection of 14 papers on the physiological features and the infl uence on their concurrent aquatic biology of diff erent cyanobacterial groups.
基金fnancially supported by the Science and Technology Commission of Shanghai Municipality(No.18DZ1205000)Natural Science Foundation of China(No.31901099)+3 种基金Yangtze Delta Estuarine Wetland Ecosystem Observation and Research Station,Ministry of Education,Shanghai Science and Technology Committee(ECNU-YDEWS-2022)Ministry of Education Key Laboratory for Biodiversity Science and Ecological Engineering,Institute of Biodiversity Science,Fudan University(2023-FDU-KF-02)Shanghai Key Lab for Urban Ecological Processes and Eco-Restoration(SHUES2023A04)“Pioneer”and“Leading Goose”R&D Program of Zhejiang(2024C02002).
文摘Ongoing wind energy developments play a key role in mitigating the global effects of climate change and the energy crisis;however,they have complex ecological consequences for many flying animals.The Yellow Sea coast is considered as an ecological bottleneck for migratory waterbirds along the East Asian–Australasian flyway(EAAF),and is also an important wind farm base in China.However,the effects of large-scale onshore wind farms along the EAAF on multidimensional waterbird diversity,and how to mitigate these effects,remain unclear.Here we examined how wind farms and their surrounding landscapes affected multidimensional waterbird diversity along the Yellow Sea coast.Taxonomic,functional,and phylogenetic diversity of the waterbird assemblages,and mean pairwise distances and nearest taxon distances with null models were quantified in relation to 4 different wind turbine densities.We also measured 6 landscape variables.Multi-dimensional waterbird diversity(taxonomic,functional,and phylogenetic diversity)significantly decreased with increasing wind turbine density.Functional and phylogenetic structures tended to be clustered in waterbird communities,and environmental filtering drove waterbird community assemblages.Furthermore,waterbird diversity was regulated by a combination of wind turbine density and landscape variables,with edge density of aquaculture ponds,in addition to wind turbine density,having the greatest independent contribution to waterbird diversity.These results suggest that attempts to mitigate the impact of wind farms on waterbird diversity could involve the landscape transformation of wind farm regions,for example,by including high-edge-density aquaculture ponds(i.e.,industrial ponds)around wind farms,instead of traditional low-edge-density aquaculture ponds.
基金supported by the National Natural Science Foundation of China Overseas and Hong Kong-Macao Scholars Collaborative Research Fund(Grant No.31728003)the Shanghai University Distinguished Professor(Oriental Scholars)Program(Grant No.JZ2016006)
文摘Coastal blue carbon refers to the carbon taken from atmospheric CO2; fixed by advanced plants(including salt marsh,mangrove, and seagrass), phytoplankton, macroalgae, and marine calcifiers via the interaction of plants and microbes; and stored in nearshore sediments and soils; as well as the carbon transported from the coast to the ocean and ocean floor. The carbon sequestration capacity per unit area of coastal blue carbon is far greater than that of the terrestrial carbon pool. The mechanisms and controls of the carbon sink from salt marshes, mangroves, seagrasses, the aquaculture of shellfish and macroalgae, and the microbial carbon pump need to be further studied. The methods to quantify coastal blue carbon include carbon flux measurements, carbon pool measurements, manipulative experiments, and modeling. Restoring, conserving, and enhancing blue carbon will increase carbon sinks and produce carbon credits, which could be traded on the carbon market. The need to tackle climate change and implement China's commitment to cut carbon emissions requires us to improve studies on coastal blue carbon science and policy. The knowledge learned from coastal blue carbon improves the conservation and restoration of salt marshes,mangroves, and seagrasses; enhances the function of the microbial carbon pump; and promotes sustainable aquaculture, such as ocean ranching.
