Late‐summer peak in sediment accumulation in two lakes with contrasting watersheds, alaska

References

• Arnold, M.S. and Kaufman, D.S., 2012. Hydro‐climate and sediment variations at Allison Lake, south‐central Alaska. In: 42nd International Arctic Workshop, Program and Abstracts 2012. Institute of Arctic and Alpine Research (INSTAAR), University of Colorado at Boulder. 6–8.
   Google Scholar
• Ashley, G.M., 1995. Glaciolacustrine environments. In: Menzies, J. (ed.), Glacial Environments: Modern Glacial Environment: Processes, Dynamics, and Sediments, vol. 1. Butterworth–Heinemann, Oxford. 417–444.
   Google Scholar
• Baker, E.T., Milburn, H.B. and Tennant, D.A., 1988. Field assessment of sediment trap efficiency under varying flow conditions. Journal of Marine Research, 46, 573–592.
   Google Scholar
• Bakke, J., Lie, Ø., Nesje, A., Dahl, S.O. and Paasche, Ø., 2005. Utilizing physical sediment variability in glacier‐fed lakes for continuous glacier reconstructions during the Holocene, northern Folgefonna, western Norway. The Holocene, 15, 161–176.
   Web of Science ®Google Scholar
• Bird, B.W., Abbott, M.B., Finney, B.P. and Kutchko, B., 2009. A 2000 year varve‐based climate record from the central Brooks Range, Alaska. Journal of Paleoliminology, 41, 25–41.
   Web of Science ®Google Scholar
• Buesseler, K.O., Antia, A.N., Chen, M., Fowler, S.W., Gardner, W.D., Gustafsson, O., Harada, K., Michaels, A.F., van Der loeff, M.R., Sarin, M., Steinberg, D.K. and Trull, T., 2007. An assessment of the use of sediment traps for estimating upper ocean particle fluxes. Journal of Marine Research, 65, 345–416.
   Web of Science ®Google Scholar
• Ceperley, E.G., 2014. Reconstructing late Pleistocene and Holocene glacier fluctuations using cosmogenic ¹⁰Be exposure dating and lacustrine sediment, Brooks Range, Arctic Alaska, Master thesis, University at Buffalo, State University of New York. 115 p.
   Google Scholar
• Cockburn, J.M.H. and Lamoureux, S.F., 2008. Inflow and lake controls on short‐term mass accumulation and sedimentary particle size in a High Arctic lake: implication for interpreting varved lacustrine sedimentary records. Journal of Paleolimnology, 40(3), 923–942. doi:10.1007/s10933‐008‐9207‐5
   Google Scholar
• Cuven, S., Francus, P. and Lamoureux, S.F., 2010. Estimation of grain size variability with micro X‐ray fluorescence in laminated lacustrine sediments, Cape Bounty, Canadian High Arctic. Journal of Paleolimnology, 44(3), 803–817.
   Google Scholar
• Fathi‐moghadam, M., Arman, A., Emamgholizadeh, S. and Alikhani, A., 2011. Settling properties of cohesive sediments in lakes and reservoirs. Journal of Waterway, Port, Coastal, and Ocean Engineering, July–August, 204–209.
   Google Scholar
• Fenn, C.R., 1987. Sediment transfer processes in Alpine glacier basins. In: Gurnell, A.M. and Clarke, M.J. (eds), Glacio‐Fluvial Sediment Transfer: An Alpine Perspective. John Wiley, Hoboken, NJ. 59–85.
   Google Scholar
• Fountain, A.G., 1996. Effect of snow and firn hydrology on the physical and chemical characteristics of glacial runoff. Hydrological Processes, 10, 509–521.
   Web of Science ®Google Scholar
• Gregory, K.J., 1987. The hydrogeomorphology of alpine proglacial areas. In: Gurnell, A.M. and Clarke, M.J. (eds), Glacio‐Fluvial Sediment Transfer: An Alpine Perspective. John Wiley, Hoboken, NJ. 87–107.
   Google Scholar
• Hammer, K.M. and Smith, N.D., 1983. Sediment production and transport in a proglacial stream: Hilda Glacier, Alberta, Canada. Boreas, 12, 91–106.
   Web of Science ®Google Scholar
• Hawley, N. and Eddie, B.J., 2007. Observations of sediment transport in Lake Erie during the winter of 2004–2005. Journal of Great Lakes Research, 33, 816–827.
   Google Scholar
• Hodder, K.R., 2009. Flocculation: a key process in the sediment flux of a large, glacier fed lake. Earth Surface Processes and Landforms, 34, 1151–1163. 10.1002/esp.1807
   Google Scholar
• Hodder, K.R., Gilbert, R. and Desloges, J.R., 2007. Glaciolacustrine varved sediments as alpine hydroclimatic proxy. Journal of Paleolimnology, 38, 365–394.
   Web of Science ®Google Scholar
• Hughen, K.A., Overpeck, J.T. and Anderson, R.F., 2000. Recent warming in a 500‐year paleotemperature record from varved sediments, Upper Soper Lake, Baffin Island, Canada. The Holocene, 10, 9–19.
   Web of Science ®Google Scholar
• Lambert, A. and Giovanoli, F., 1988. Records of river born turbidity currents and indicator of slope failure in the Rhône delta of Lake Geneva. Limnology and Oceanography, 33, 458–468.
   Web of Science ®Google Scholar
• Lapointe, F., Francus, P., Lamoureux, S., Saïd, M. and Cuven, S., 2012. 1,750 years of large rainfall events inferred from particle size at East Lake, Cape Bounty, Melville Island, Canada. Journal of Paleolimnology, 48, 159–173.
   Google Scholar
• Larsen, D.J., Miller, G.H., Geirsdottir, A. and Thordarson, T., 2011. A 3000‐year varved record of glacier activity and climate change from the proglacial lake Hvitarvatn, Iceland. Quaternary Science Reviews, 30, 2715–2731.
   Google Scholar
• Leonard, E.M., 1997. The relationship between glacial activity and sediment production: evidence from a 4450‐year varve record of Neoglacial sedimentation in Hector Lake, Alberta, Canada. Journal of Paleolimnology, 17, 319–330.
   Web of Science ®Google Scholar
• Muzzi, R.W. and Eadie, B.J., 2002. The design and performance of a sequencing sediment trap for lake research. Marine Technology Society Journal, 36, 2–28.
   Google Scholar
• O'brien, N.R. and Pietraszek‐mattner, S., 1998. Origin of the fabric of laminated fine‐grained glaciolacustrine deposits. Journal of Sedimentary Research, 68, 832–840.
   Google Scholar
• Ojala, A.E.K., Francus, P., Zolitschka, B., Besonen, M. and Lamoureux, S.F., 2012. Characteristics of sedimentary varve chronologies – a review. Quaternary Science Review, 43, 45–60.
   Web of Science ®Google Scholar
• Orwin, J.F., Lamoureux, S.F., Warburton, J. and Beylich, A., 2010. A framework for characterizing fluvial sediment fluxes from source to sink in cold environments. Geografiska. Annaler: Series A, Physical Geography 92(2): 155–176.
   Web of Science ®Google Scholar
• Riihimaki, C.A., Macgregor, K.R., Anderson, R.S., Anderson, S.P. and Loso, M.G., 2005. Sediment evacuation and glacial erosion rates at a small alpine glacier. Journal of Geophysical Research, 110, F03003.
   Web of Science ®Google Scholar
• Röthlisberger, H. and Lang, H., 1987. Glacial hydrology. In: Gurnell, A.M. and Clarke, M.J. (eds), Glacio‐Fluvial Sediment Transfer: An Alpine Perspective. John Wiley, Hoboken, NJ. 207–284.
   Google Scholar
• Samadi‐boroujeni, H., Fathi‐moghaddam, M., Shafaie, M. and Samani, H., 2005. Modelling of sedimentation and self‐weight consolidation of cohesive sediments. In: Kusuda, T., Yamanishi, H., Spearmant, J. and Gailani, J.Z. (eds), Sediment and Ecohydraulics, 1st edition. Elsevier, Oxford. 502.
   Google Scholar
• Schiefer, E., Gilbert, R. and Hassan, M.A., 2011. A lake sediment‐based proxy of floods in the Rocky Mountain Front Ranges, Canada. Journal of Paleolimnology, 45, 137–145. doi:10.1007/s10933‐010‐9485‐6
   Google Scholar
• Schiefer, E., Menounos, B. and Slaymaker, O., 2006. Extreme sediment delivery events recorded in the contemporary record of a montane lake, southern Coast Mountains, British Columbia. Canadian Journal of Earth Sciences, 43, 1777–1790.
   Web of Science ®Google Scholar
• Smith, N.D., 1981. The effect of changing sediment supply on sedimentation in a glacier‐fed lake. Arctic and Alpine Research, 13, 195–209.
   Google Scholar
• Smith, N.D., Venol, M.A. and Kennedy, S.K., 1982. Comparison of sedimentation regimes in four glacier‐fed lakes of western Alberta. In: Davidson‐arnott, R., Nickling, W. and Fahey, B.D. (eds), Research in Glacial, Glacio‐fluvial, and Glacio‐lacustrine Systems. Geo Books, Norwich. 203–238.
   Google Scholar