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A high-resolution paleolimnological study of climate and human impacts on Lac Noir, Québec, over the past 1000 yr

Published online by Cambridge University Press:  05 November 2018

Karen Neil*
Affiliation:
Laboratory of Paleoclimatology and Climatology, Department of Geography, Environment and Geomatics, University of Ottawa, Ottawa, Ontario K1N6N5, Canada
Konrad Gajewski
Affiliation:
Laboratory of Paleoclimatology and Climatology, Department of Geography, Environment and Geomatics, University of Ottawa, Ottawa, Ontario K1N6N5, Canada
*
*Corresponding author at: Laboratory of Paleoclimatology and Climatology, Department of Geography, Environment and Geomatics, University of Ottawa, Ottawa, Ontario K1N6N5, Canada. E-mail address: [email protected] (K. Neil).

Abstract

Diatom assemblages in lake sediments of Lac Noir, southwestern Québec, were studied at a resolution of 10 yr to determine principal drivers of primary producers for the past ~1000 yr. Generalized additive modeling revealed strong links between broadscale climate intervals of the late Holocene, forest composition, and diatom flora. During the Medieval Warm Period (~AD 1200) and onset of the Little Ice Age (~AD 1450), increases in Tabellaria flocculosa str. IIIp at the expense of Discostella stelligera reflected low lake productivity. At AD 1630, an abrupt shift to cooler temperatures and dry conditions triggered a decline in hemlock (Tsuga), replaced by disturbance and cool-adapted taxa. Greater nutrient availability and soil erosion in the catchment led to a corresponding and rapid increase in diatoms with higher optima for nitrogen, such as Asterionella formosa and Fragilaria crotonensis. After AD 1870, an increase in pollen of taxa associated with disturbances signaled the arrival of Euro-Canadians, and associated nutrient inputs to the lake triggered increases in Stephanodiscus minutulus and Achnanthidium minutissimum. Overall results of the study indicate that climate played an important underlying role in lake-ecosystem dynamics; however, disturbances affecting forest composition had more direct influences on the diatom communities of Lac Noir.

Type
Research Article
Copyright
Copyright © University of Washington. Published by Cambridge University Press, 2018 

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References

REFERENCES

Antoniades, D., Hamilton, P.B., Douglas, M.S.V., Smol, J.P., 2008. Diatoms of North America: the Freshwater Flora of Prince Patrick, Ellef Ringnes, and Northern Ellesmere Islands from the Canadian Arctic Archipelago. Iconographia Diatomologica, Vol. 17. A.R. Gantner Verlag KG, Ruggell, Liechtenstein.Google Scholar
Arnett, H.A., Saros, J.E., Mast, M.A., 2012. A caveat regarding diatom-inferred nitrogen concentrations in oligotrophic lakes. Journal of Paleolimnology 47, 277291.Google Scholar
Barker, P.A., Pates, J.M., Payne, R.J., Healey, R.M., 2005. Changing the nutrient levels in Grasmere, English Lake District, during recent centuries. Freshwater Biology 50, 19711981.Google Scholar
Battarbee, R.W., Jones, V.J., Cameron, N.G., Bennion, H., Carvalho, L., Juggins, S., 2001. Diatoms. In: Smol, J.P., Birks, H.J.B., Last, W.M. (Eds.), Tracking Environmental Change Using Lake Sediments. Kluwer, Dordrecht, the Netherlands, pp. 155202.Google Scholar
Beck, K.K., Medeiros, A.S., Finkelstein, S.A., 2016. Drivers of change in a 7300-year Holocene diatom record from the Hemi-Boreal region of Ontario, Canada. PLoS ONE 11, e0159937.Google Scholar
Blanco, S., 2014. Environmental factors controlling lake diatom communities: a meta-analysis of published data. Biogeosciences Discussions 11, 1588915909.Google Scholar
Boulanger, Y., Taylor, A.R., Price, D.T., Cyr, D., McGarrigle, E., Rammer, W., Sainte-Maire, G., Beaudoin, A., Guindon, L., Mansuy, N., 2017. Climate change impacts on forest landscapes along the Canadian southern boreal forest transition zone. Landscape Ecology 32, 14151431.Google Scholar
Boyle, J.F., 2007. Loss of apatite caused irreversible early Holocene lake acidification. Holocene 17, 543547.Google Scholar
Bradshaw, E.G., Rasmussen, P., Nielsen, H., Anderson, N.J., 2005. Mid- to late-Holocene land-use change and lake development at Dallund Sø, Denmark: trends in lake primary production as reflected by algal and macrophyte remains. Holocene 15, 11301142.Google Scholar
Camburn, K.E., Charles, D.F., 2000. Diatoms of Low-Alkalinity Lakes in the Northeastern United States. Academy of Natural Sciences of Philadelphia Special Publication 18. Philadelphia. Academy of Natural Sciences of Philadelphia, Philadelphia, PA.Google Scholar
Carignan, R., Steedman, R.J., 2000. Impacts of major watershed perturbations on aquatic ecosystems. Canadian Journal of Fisheries and Aquatic Sciences 57, Suppl. 2, 14.Google Scholar
Christie, C.E., Smol, J.P., 1993. Diatom assemblages as indicators of lake trophic status in southeastern Ontario lakes. Journal of Phycology 29, 575586.Google Scholar
Cooper, E., Neil, K., Gajewski, K., 2016. Spatial and temporal cladoceran community responses to environmental change and anthropogenic impacts in southwestern Québec. Écoscience 23, 97112.Google Scholar
Dove-Thompson, D., Lewis, C., Gray, P.A., Chu, C., Dunlop, W.I., 2011. A summary of the effects of climate change on Ontario’s aquatic ecosystems. In: Ontario Ministry of Natural Resources (Ed.), Climate Change Research Report CCRR-11. Queen’s Printer for Ontario, ON, Canada, pp. 156.Google Scholar
Ekdahl, E.J., Teranes, J.L., Wittkop, C.A., Stoermer, E.F., Reavie, E.D., Smol, J.P., 2007. Diatom assemblage response to Iroquoian and Euro-Canadian eutrophication of Crawford Lake, Ontario, Canada. Journal of Paleolimnology 37, 233246.Google Scholar
Engstrom, D.R., Wright, H.E., 1984. Chemical stratigraphy of lake sediments as a record of environmental change. In: Haworth, E.Y., Lund, J.W.G. (Eds.), Lake Sediments and Environmental History. Leicester University Press, Leicester, pp. 11e69.Google Scholar
Faulkenham, S.E., Hall, R.I., Dillon, P.J., Karst-Riddoch, T., 2003. Effects of drought-induced acidification on diatom communities in acid-sensitive Ontario lakes. Limnology and Oceanography 48, 16621673.Google Scholar
Fritz, S.C., Anderson, N.J., 2013. The relative influences of climate and catchment processes on Holocene lake development in glaciated regions. Journal of Paleolimnology 49, 349362.Google Scholar
Gajewski, K., 1988. Late Holocene climate changes in eastern North America estimated from pollen data. Quaternary Research 29, 255262.Google Scholar
Haig, H.A., Kingsbury, M.V., Laird, K.R., Leavitt, P.R., Laing, R., Cumming, B., 2013. Assessment of drought over the past two millennia using near-shore sediment cores from a Canadian Boreal lake. Journal of Paleolimnology 50, 175190.Google Scholar
Hall, R.I., Smol, J.P., 1993. The influence of catchment size on lake trophic status during the hemlock decline and recovery (4800 to 3500 BP) in southern Ontario lakes. Hydrobiologia 269, 371390.Google Scholar
Hall, R.I., Smol, J.P., 1996. Paleolimnological assessment of long-term water-quality changes in south-central Ontario lakes affected by cottage development and acidification. Canadian Journal of Fisheries and Aquatic Sciences 53, 117.Google Scholar
Harris, M.A., Cumming, B.F., Smol, J.P., 2006. Assessment of recent environmental changes in New Brunswick (Canada) lakes based on paleolimnological shifts in diatom species assemblages. Canadian Journal of Botany 84, 151163.Google Scholar
Johnstone, J.F., Allen, C.D., Franklin, J.F., Turner, M.G., 2016. Changing disturbance regimes, ecological memory, and forest resilience. Frontiers in Ecology and the Environment 14, 369378.Google Scholar
Karmakar, M., Laird, K.R., Cumming, B.F., 2015. Diatom-based evidence of regional aridity during the mid-Holocene period in boreal lakes from northwest Ontario (Canada). Holocene 25, 166177.Google Scholar
Karst, T.L., Smol, J.P., 2000. Paleolimnological evidence of limnetic nutrient concentration equilibrium in a shallow, macrophyte-dominated lake. Aquatic Sciences 62, 2038.Google Scholar
Kirilova, E., Heiri, O., Enters, D., Cremer, H., Lotter, A.F., Zolitschka, B., Hübener, T., 2009. Climate-induced changes in the trophic status of a Central European lake. Journal of Limnology 68, 7182.Google Scholar
Köster, D., Pienitz, R., 2006. Seasonal diatom variability and paleolimnological inferences – a case study. Journal of Paleolimnology 35, 395416.Google Scholar
Köster, D., Pienitz, R., Wolfe, B.B., Barry, S., Foster, D.R., Dixit, S.S., 2005. Paleolimnological assessment of human-induced impacts on Walden Pod (Massachusetts, USA) using diatoms and stable isotopes. Aquatic Ecosystem Health & Management 8, 117131.Google Scholar
Lafontaine-Boyer, K., Gajewski, K., 2014. Vegetation dynamics in relation to late Holocene climate variability and disturbance, Outaouais, Québec, Canada. Holocene 24, 15151526.Google Scholar
Lavery, J.M., Kurek, J., Rühland, K.M., Gillis, C.A., Pisaric, M.J.F., Smol, J.P., 2014. Exploring the environmental context of recent Didymosphenia geminata proliferation in Gaspésie, Québec, using paleolimnology. Canadian Journal of Fisheries and Aquatic Sciences 71, 616626.Google Scholar
Legendre, P., Gallagher, E.D., 2001. Ecologically meaningful transformations for ordination of species data. Oecologia 129, 271280.Google Scholar
Lotter, A.F., 1998. The recent eutrophication of Balderggersee (Switzerland) as assessed by fossil diatom assemblages. Holocene 8, 395405.Google Scholar
Mann, M.E., Zhang, Z., Hughes, M.K., Bradley, R.S., Miller, S.K., Rutherford, S., Ni, F., 2008. Proxy-based reconstructions of hemispheric and global surface temperature variations over the past two millennia. Proceedings of the National Academy of Sciences of the United States of America, 105, 1325213257.Google Scholar
Marra, G., Wood, S.N., 2011. Practical variable selection for generalized additive models. Computational Statistics & Data Analysis 55, 23722387.Google Scholar
Morabito, G., Oggioni, A., Austoni, M., 2012. Resource ratio and human impact: how diatom assemblages in Lake Maggiore responded to oligotrophication and climate variability. Hydrobiologia 698, 4760.Google Scholar
Neil, K., Gajewski, K., 2017. Impacts of late-Holocene climate variability and watershed-lake interactions on diatom communities in Lac Brûlé, Québec. Ecosphere 8, e01886.Google Scholar
Paine, R.T., Tegner, M.J., Johnson, E.A., 1998. Compounded perturbations yield ecological surprises. Ecosystems 1, 535545.Google Scholar
Pappas, J.L., 2010. Phytoplankton assemblages, environmental influences and trophic status using canonical correspondence analysis, fuzzy relations, and linguistic translation. Ecological Informatics 5, 7988.Google Scholar
Paquette, N., Gajewski, K., 2013. Climatic change causes abrupt changes in forest composition, inferred from a high resolution pollen record, southwestern Quebec, Canada. Quaternary Science Reviews 75, 169180.Google Scholar
Patrick, R., Reimer, C.W., 1966. The Diatoms of the United States. Vol. 1. Sutter House, Lititz, PA.Google Scholar
Patrick, R., Reimer, C.W., 1975. The Diatoms of the United States. Vol. 2, Part 1. Sutter House, Lititz, PA.Google Scholar
Perren, B.B., Douglas, M.S.V., Anderson, N.J., 2009. Diatoms reveal complex spatial and temporal patterns of recent limnological change in West Greenland. Journal of Paleolimnology 42, 233247.Google Scholar
Philibert, A., Prairie, Y.T., Carcaillet, C., 2003. 1200 Years of fire impact on biogeochemistry as inferred from high resolution diatom analysis in a kettle lake from the Picea mariana-moss domain (Québec, Canada). Journal of Paleolimnology 30, 167181.Google Scholar
Puusepp, L., Kangur, M., 2010. Linking diatom community dynamics to changes in terrestrial vegetation: a palaeolimnological case study of Lake Ķūzi, Vidzeme Heights (central Latvia). Estonian Journal of Ecology 59, 259280.Google Scholar
Rawlence, D.J., 1992. Paleophycology of Long Lake, Saint John County, New Brunswick, Canada, based on diatom distribution in sediments. Canadian Journal of Botany 70, 229239.Google Scholar
R Development Core Team, 2013. R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, Vienna, Austria.Google Scholar
Riemersma, S., Little, J., Ontkean, G., Moskal-Hébert, T., 2006. Phosphorus sources and sinks in watersheds: a review. In: Alberta Soil Phosphorus Limits Project. Vol. 5, Background Information and Reviews. Alberta Agriculture, Food and Rural Development, Lethbridge, AB, Canada, pp. 182.Google Scholar
Rosén, P., Hammarlund, D., 2007. Effects of climate, fire, and vegetation development on Holocene changes in total organic carbon concentration in three boreal forest lakes in northern Sweden. Biogeosciences 4, 975984.Google Scholar
Rühland, K.M., Paterson, A.M., Smol, J.P., 2015. Lake diatom responses to warming: reviewing the evidence. Journal of Paleolimnology 54, 135.Google Scholar
Saros, J.E., Anderson, N.J., 2015. The ecology of the planktonic diatom Cyclotella and its implications for global environmental change studies. Biological Reviews 90, 522541.Google Scholar
Saros, J.E., Michel, T.J., Interlandi, S.J., Wolfe, A.P., 2005. Resource requirements of Asterionella formosa and Fragilaria crotonensis in oligotrophic alpine lakes: implications for recent phytoplankton community reorganizations. Canadian Journal of Fisheries and Aquatic Sciences 62, 16811689.Google Scholar
Sheilbley, R.W., Enache, M., Swarzenski, P.W., Moran, P.W., Foreman, J.R., 2014. Nitrogen deposition effects on diatom communities in lakes from three national parks in Washington State. Water, Air, & Soil Pollution 225, 1857.Google Scholar
Siver, P.A., Hamilton, P.B., Stachura-Suchoples, K., Kociolek, J.P., 2005. Diatoms of North America: The Freshwater Flora of Cape Cod, Massachusetts, U.S.A. Iconographia Diatomologica, Vol. 14. A.R. Gantner Verlag KG, Ruggell, Liechtenstein.Google Scholar
Smith, W.V., 1967. The Evolution of a Fall Line Settlement, Buckingham, Québec. Master’s thesis, University of Ottawa, Ottawa, ON, Canada.Google Scholar
Smol, J.P. 1985. The ratio of diatom frustules to chrysophycean statospores: a useful paleolimnological index. Hydrobiologia 123, 199208.Google Scholar
Stager, J.C., Cumming, B.F., Laird, K.R., Garrigan-Piela, A., Neil, P., Wiltse, B., Lane, C.S., Nester, J., Ruzmaikin, A., 2017. A 1600-year diatom record of hydroclimate variability from Wolf Lake, New York. Holocene 27, 246257.Google Scholar
Stevenson, A.C., Jones, V.J., Battarbee, R.W., 1990. The cause of peat erosion: a palaeolimnological approach. New Phytologist 114, 727735.Google Scholar
Stoermer, E.F., Smol, J.P., 2001. The Diatoms: Applications for the Environmental and Earth Sciences. Cambridge University Press, New York, NY.Google Scholar
Tremblay, R., Pienitz, R., Legendre, P., 2014. Reconstructing phosphorous levels using models based on the modern diatom assemblages of 55 lakes in southern Québec. Canadian Journal of Fisheries and Aquatic Sciences 71, 887914.Google Scholar
Viau, A.E., Gajewski, K., Sawada, M.C., Fines, P., 2006. Millennial-scale temperature variability in North America during the Holocene. Journal of Geophysical Research-Atmospheres 111, D09102.Google Scholar
Viau, A.E., Ladd, M., Gajewski, K., 2012. The climate of North America during the past 2000 years reconstructed from pollen data. Global and Planetary Change 84–85, 7583.Google Scholar
Vitousek, P.M., Aber, J.D., Howarth, R.W., Likens, G.E., Matson, P.A., Schindler, D.W., Schlesinger, W.H., Tilman, D.G., 1997. Human alteration of the global nitrogen cycle: sources and consequences. Ecological Applications 7, 737750.Google Scholar
Williams, J.W., Blois, J.L, Shuman, B.N., 2011. Extrinsic and intrinsic forcing of abrupt ecological change: case studies from the late Quaternary. Journal of Ecology 99, 664677.Google Scholar
Williams, J.W., Post, D.M., Cwynar, L.C., Lotter, A.F., Levesque, A.J., 2002. Rapid and widespread vegetation responses to past climate change in the North Atlantic region. Geology 30, 971974.Google Scholar
Wolin, J.A., Stoermer, E.F., 2005. Response of a Lake Michigan coastal lake to anthropogenic catchment disturbance. Journal of Paleolimnology 33, 7394.Google Scholar
Wood, S.N., 2008. Fast stable direct fitting and smoothness selection for generalized additive models. Journal of the Royal Statistical Society B 70, 495518.Google Scholar
Wood, S.N., 2011. Fast restricted maximum likelihood and marginal likelihood estimation of semiparametric generalized linear models. Journal of the Royal Statistical Society B 73, 336.Google Scholar
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