Differences in food web structure and composition between new and nearby older lakes in West Greenland suggest succession trajectories driven by glacier retreat

[1]  J. Elser,et al.  Key rules of life and the fading cryosphere: Impacts in alpine lakes and streams , 2020, Global change biology.

[2]  Jeffrey S. Kargel,et al.  Rapid worldwide growth of glacial lakes since 1990 , 2020, Nature Climate Change.

[3]  R. Sommaruga,et al.  Food Web Complexity of High Mountain Lakes is Largely Affected by Glacial Retreat , 2019, Ecosystems.

[4]  M. Morlighem,et al.  The impact of model resolution on the simulated Holocene retreat of the southwestern Greenland ice sheet using the Ice Sheet System Model (ISSM) , 2018, The Cryosphere.

[5]  A. Michelsen,et al.  What drives biological nitrogen fixation in high arctic tundra: Moisture or temperature? , 2018 .

[6]  H. Peter,et al.  Changes in bacterioplankton community structure during early lake ontogeny resulting from the retreat of the Greenland Ice Sheet , 2017, The ISME Journal.

[7]  E. Jeppesen,et al.  The structuring role of fish in Greenland lakes: an overview based on contemporary and paleoecological studies of 87 lakes from the low and the high Arctic , 2017, Hydrobiologia.

[8]  E. Jeppesen,et al.  Environment not dispersal limitation drives clonal composition of Arctic Daphnia in a recently deglaciated area , 2016, Molecular ecology.

[9]  R. Sommaruga,et al.  Ciliate community structure and interactions within the planktonic food web in two alpine lakes of contrasting transparency , 2016, Freshwater biology.

[10]  E. Jeppesen,et al.  Colonization history and clonal richness of asexual Daphnia in periglacial habitats of contrasting age in West Greenland. , 2016, The Journal of animal ecology.

[11]  R. Sommaruga When glaciers and ice sheets melt: consequences for planktonic organisms. , 2015, Journal of plankton research.

[12]  H. Mariash,et al.  Benthic mats offer a potential subsidy to pelagic consumers in tundra pond food webs , 2014 .

[13]  R. Sommaruga,et al.  Negative consequences of glacial turbidity for the survival of freshwater planktonic heterotrophic flagellates , 2014, Scientific Reports.

[14]  D. Pawłowski,et al.  Changes in the biota and sediments of glacial Lake Koźmin, Poland, during the late Saalian (Illinoian) , 2013, Journal of Paleolimnology.

[15]  J. Saros,et al.  Implications of nitrogen‐rich glacial meltwater for phytoplankton diversity and productivity in alpine lakes , 2012 .

[16]  A. Michelsen,et al.  Benthic resources are the key to Daphnia middendorffiana survival in a high arctic pond , 2012 .

[17]  E. Jeppesen,et al.  Inferring a single variable from an assemblage with multiple controls: getting into deep water with cladoceran lake-depth transfer functions , 2011, Hydrobiologia.

[18]  C. Sayer,et al.  Zooplankton as indicators in lakes: a scientific-based plea for including zooplankton in the ecological quality assessment of lakes according to the European Water Framework Directive (WFD) , 2011, Hydrobiologia.

[19]  Andrew L Jackson,et al.  Comparing isotopic niche widths among and within communities: SIBER - Stable Isotope Bayesian Ellipses in R. , 2011, The Journal of animal ecology.

[20]  S. Carpenter,et al.  Strong evidence for terrestrial support of zooplankton in small lakes based on stable isotopes of carbon, nitrogen, and hydrogen , 2011, Proceedings of the National Academy of Sciences.

[21]  K. Rose,et al.  Melting Alpine glaciers enrich high-elevation lakes with reactive nitrogen. , 2010, Environmental science & technology.

[22]  G. Weyhenmeyer,et al.  Lakes as sentinels of climate change , 2009, Limnology and oceanography.

[23]  U. Sommer,et al.  Global warming benefits the small in aquatic ecosystems , 2009, Proceedings of the National Academy of Sciences.

[24]  T. Schenk,et al.  Intermittent thinning of Jakobshavn Isbræ, West Greenland, since the Little Ice Age , 2008, Journal of Glaciology.

[25]  W. Vincent,et al.  Isotopic analysis of the sources of organic carbon for zooplankton in shallow subarctic and arctic waters , 2007 .

[26]  W. Vincent,et al.  Benthic and pelagic food resources for zooplankton in shallow high‐latitude lakes and ponds , 2006 .

[27]  E. B. Karabanov,et al.  Ecological collapse of Lake Baikal and Lake Hovsgol ecosystems during the Last Glacial and consequences for aquatic species diversity , 2004 .

[28]  David M. Lodge,et al.  From Greenland to green lakes : Cultural eutrophication and the loss of benthic pathways in lakes , 2003 .

[29]  U. Uehlinger,et al.  Nutrients and organic matter in a glacial river—floodplain system (Val Roseg, Switzerland) , 2002 .

[30]  P. Legendre,et al.  Ecologically meaningful transformations for ordination of species data , 2001, Oecologia.

[31]  E. Jeppesen,et al.  Trophic structure in the pelagial of 25 shallow New Zealand lakes: changes along nutrient and fish gradients , 2000 .

[32]  K. Hobson,et al.  Cannibalism and trophic structure in a high Arctic lake: insights from stable-isotope analysis , 1995 .

[33]  J. Koenings,et al.  The Exclusion of Limnetic Cladocera from Turbid Glacier-Meltwater Lakes , 1990 .

[34]  K. Christoffersen,et al.  Measurements of chlorophyll-a from phytoplankton using ethanol as extraction solvent , 1987, Archiv für Hydrobiologie.

[35]  Robert H. Peters,et al.  Empirical Prediction of Crustacean Zooplankton Biomass and Profundal Macrobenthos Biomass in Lakes , 1984 .

[36]  J. Sharp,et al.  Determination of total dissolved nitrogen in natural waters1 , 1980 .

[37]  E. Odum The strategy of ecosystem development. , 1969, Science.

[38]  Erik Jeppesen,et al.  Temperature effects on body size of freshwater crustacean zooplankton from Greenland to the tropics , 2014, Hydrobiologia.

[39]  D. Hoeinghaus,et al.  Can stable isotope ratios provide for community-wide measures of trophic structure? Comment. , 2008, Ecology.