Synergistic Effects of Warming and Internal Nutrient Loading Interfere with the Long-Term Stability of Lake Restoration and Induce Sudden Re-eutrophication
暂无分享,去创建一个
K. Rinke | D. Pujoni | A. Janssen | C. Barbosa | T. K. Andersen | M. Schultze | M. Paule-Mercado | Maria Determann | Xiangzhen Kong | T. Dadi | Karsten Rinke
[1] K. Bolding,et al. Simulating shifting ecological states in a restored, shallow lake with multiple single-model ensembles: Lake Arreskov, Denmark , 2022, Environ. Model. Softw..
[2] Yiheng Du,et al. From macrophyte to algae: Differentiated dominant processes for internal phosphorus release induced by suspended particulate matter deposition. , 2022, Water research.
[3] M. Rode,et al. Reservoir water quality deterioration due to deforestation emphasizes the indirect effects of global change. , 2022, Water research.
[4] K. Bolding,et al. Water Ecosystems Tool (WET) 1.0 – a new generation of flexible aquatic ecosystem model , 2022, Geoscientific Model Development.
[5] Lian Feng,et al. Global mapping reveals increase in lacustrine algal blooms over the past decade , 2022, Nature Geoscience.
[6] H. Paerl,et al. Feedback between climate change and eutrophication: revisiting the allied attack concept and how to strike back , 2022, Inland Waters.
[7] Tadhg N. Moore,et al. A framework for ensemble modelling of climate change impacts on lakes worldwide: the ISIMIP Lake Sector , 2022, Geoscientific Model Development.
[8] D. Pierson,et al. Attribution of global lake systems change to anthropogenic forcing , 2021, Nature Geoscience.
[9] Maria do Carmo Calijuri,et al. Deterministic modelling of freshwater lakes and reservoirs: Current trends and recent progress , 2021, Environ. Model. Softw..
[10] Lesley B. Knoll,et al. Widespread deoxygenation of temperate lakes , 2021, Nature.
[11] Lesley B. Knoll,et al. Climate change drives widespread shifts in lake thermal habitat , 2021, Nature Climate Change.
[12] H. Rönicke,et al. Suppression of bloom-forming colonial cyanobacteria by phosphate precipitation: A 30 years case study in Lake Barleber (Germany) , 2021 .
[13] Peter J. Alsip,et al. Continuous In Situ Nutrient Analyzers Pinpoint the Onset and Rate of Internal P Loading under Anoxia in Lake Erie’s Central Basin , 2021 .
[14] E. van Donk,et al. The value of novel ecosystems: Disclosing the ecological quality of quarry lakes. , 2021, The Science of the total environment.
[15] Xiangzhen Kong,et al. Unravelling winter diatom blooms in temperate lakes using high frequency data and ecological modeling. , 2020, Water research.
[16] David P. Hamilton,et al. Deeper waters are changing less consistently than surface waters in a global analysis of 102 lakes , 2020, Scientific Reports.
[17] Qi Miao,et al. Lake warming intensifies the seasonal pattern of internal nutrient cycling in the eutrophic lake and potential impacts on algal blooms. , 2020, Water research.
[18] George B. Arhonditsis,et al. A system of metrics for the assessment and improvement of aquatic ecosystem models , 2020, Environ. Model. Softw..
[19] Dennis Trolle,et al. Predicting ecosystem state changes in shallow lakes using an aquatic ecosystem model: Lake Hinge, Denmark, an example , 2020, Ecological applications : a publication of the Ecological Society of America.
[20] J C Ho,et al. Widespread global increase in intense lake phytoplankton blooms since the 1980s , 2019, Nature.
[21] Ana I. Ayala,et al. Simulations of future changes in thermal structure of Lake Erken: proof of concept for ISIMIP2b lake sector local simulation strategy , 2019, Hydrology and Earth System Sciences.
[22] H. Paerl,et al. Why Lake Taihu continues to be plagued with cyanobacterial blooms through 10 years (2007-2017) efforts. , 2019, Science bulletin.
[23] Robert J. Brederveld,et al. Towards restoring urban waters: understanding the main pressures , 2019, Current Opinion in Environmental Sustainability.
[24] Robert J. Brederveld,et al. Modeling water quality in the Anthropocene: directions for the next-generation aquatic ecosystem models , 2019, Current Opinion in Environmental Sustainability.
[25] H. Paerl,et al. Cyanobacterial blooms , 2018, Nature Reviews Microbiology.
[26] E. Jeppesen,et al. Gravel pit lakes in Denmark: Chemical and biological state. , 2018, The Science of the total environment.
[27] W. Mooij,et al. Hydrological regulation drives regime shifts: evidence from paleolimnology and ecosystem modeling of a large shallow Chinese lake , 2017, Global change biology.
[28] M. Antonellini,et al. Water and (bio)chemical cycling in gravel pit lakes: A review and outlook , 2016 .
[29] Luuk P. A. van Gerven,et al. FABM-PCLake – linking aquatic ecology with hydrodynamics , 2016 .
[30] H. Jensen,et al. Longevity and effectiveness of aluminum addition to reduce sediment phosphorus release and restore lake water quality. , 2016, Water research.
[31] J. Lewandowski,et al. Long-term efficiency of lake restoration by chemical phosphorus precipitation: Scenario analysis with a phosphorus balance model. , 2016, Water research.
[32] P. Raymond,et al. Large contribution to inland water CO2 and CH4 emissions from very small ponds , 2016 .
[33] Karsten Bolding,et al. A general framework for aquatic biogeochemical models , 2014, Environ. Model. Softw..
[34] O. Köster,et al. Long‐term changes in hypoxia and soluble reactive phosphorus in the hypolimnion of a large temperate lake: consequences of a climate regime shift , 2014, Global change biology.
[35] F. Piontek,et al. The Inter-Sectoral Impact Model Intercomparison Project (ISI–MIP): Project framework , 2013, Proceedings of the National Academy of Sciences.
[36] Joseph H. A. Guillaume,et al. Characterising performance of environmental models , 2013, Environ. Model. Softw..
[37] L. Pfister,et al. Hydrogeologic and landscape controls of dissolved inorganic nitrogen (DIN) and dissolved silica (DSi) fluxes in heterogeneous catchments , 2012 .
[38] David P. Hamilton,et al. Eco-physiological adaptations that favour freshwater cyanobacteria in a changing climate. , 2012, Water research.
[39] R. Pesch,et al. Mapping background values of atmospheric nitrogen total depositions in Germany based on EMEP deposition modelling and the European Moss Survey 2005 , 2011 .
[40] R. Alexander,et al. The regional and global significance of nitrogen removal in lakes and reservoirs , 2009 .
[41] Michael Hupfer,et al. Oxygen Controls the Phosphorus Release from Lake Sediments – a Long‐Lasting Paradigm in Limnology , 2008 .
[42] J. Huisman,et al. Summer heatwaves promote blooms of harmful cyanobacteria , 2008 .
[43] Barbara A. Adams-Vanharn,et al. Evaluation of the current state of mechanistic aquatic biogeochemical modeling: citation analysis and future perspectives. , 2006, Environmental science & technology.
[44] J. Berkowitz,et al. Influence of aging on phosphorus sorption to alum floc in lake water. , 2006, Water research.
[45] Rainer Brüggemann,et al. SPIEL—a model for phosphorus diagenesis and its application to lake restoration , 2004 .
[46] Penny J Johnes,et al. Evaluation and management of the impact of land use change on the nitrogen and phosphorus load delivered to surface waters: the export coefficient modelling approach , 1996 .
[47] H. Jensen,et al. Importance of temperature, nitrate, and pH for phosphate release from aerobic sediments of four shallow, eutrophic lakes , 1992 .