DOCSLIB.ORG

Dry Climate Disconnected the Laurentian Great Lakes

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Dry Climate Disconnected the Laurentian Great Lakes VOLUME 89 NUMBER 52 23 DECEMBER 2008 Dry Climate Disconnected the Laurentian Great Lakes Recent studies have produced a new of the moisture originates from humid air understanding of the hydrological history masses arising in the Gulf of Mexico and the of North America’s Great Lakes, showing subtropical North Atlantic Ocean. This inter- that water levels fell several meters below play of air masses maintains positive sur- lake basin outlets during an early postgla- face water balance, sustaining major rivers cial dry climate in the Holocene (younger and shipping canals between lakes, as well than 10,000 radiocarbon years, or about as discharge to the St. Lawrence River (Fig- 11,500 calibrated or calendar years before ure 1b). Although researchers have tradition- present (B.P.)). Water levels in the Huron ally assumed the Great Lakes to have been basin, for example, fell more than 20 meters hydrologically open since their formation below the basin overflow outlet between after 16,000 radiocarbon (19,200 calibrated) about 7900 and 7500 radiocarbon (about years B.P. during retreat of the last ice sheet 8770– 8290 calibrated) years B.P. Outlet riv- [Larson and Schaetzl, 2001], this paradigm ers, including the Niagara River, presently of continuous, abundant water supply is falling 99 meters from Lake Erie to Lake now known to be false. Mounting evidence, Ontario (and hence Niagara Falls), ran dry. described below, shows that hydrologically This newly recognized phase of low lake lev- closed lakes (i.e., lakes having water lev- els in a dry climate provides a case study for els below topographic outlets) existed in evaluating the sensitivity of the Great Lakes the Huron and Michigan basins, and likely to current and future climate change. in other basins, approximately 7900 radio- carbon or 8770 calibrated years B.P. The Laurentian Great Lakes New Understanding of Great Lakes History Collectively, these Great Lakes consti- tute one of the largest surface reservoirs Previous interpretations of past Great of freshwater on Earth. The lakes con- Lakes water levels lacked key information tain 23,000 cubic kilo meters of water, of on the altitude of outlets during glacial Fig. 2. (a) Lake level (blue) in Huron basin compared with the outlet elevation at North Bay which less than 1% is replenished annually rebound. Consequently, evidence for low- (gray) showing hydrologically closed lowstand when the lake fell by more than 20 meters below 14 14 by precipitation. Situated in the east cen- stands (lakes below present level) was taken the basin outlet after 8000 C (~8890 calibrated) years B.P. (b) Lowstand shorelines ~7900 C tral part of North America and shared by to indicate that lakes overflowed more north- (~8770 calibrated) years B.P. are shown in black, and present shorelines appear white in this colored watershed relief map. Lake basins: H, Huron; G, Georgian Bay; E, Erie; O, Ontario. (c) Tem- the United States and Canada (Figures 1a erly outlets that were still depressed isostati- perature and moisture trends relative to present conditions (dashed lines) for the southeastern and 1b), the five lake basins and their eco- cally by the previous ice load [e.g., Hough, Great Lakes region [Edwards et al., 1996]. Large black arrows indicate the time of the lowstands. systems support a population of more than 1962]. However, a greater understanding has 33 million people (in 1990– 1991) and host emerged from new empirical evidence and well- developed industries for shipping, fish- more precise analysis and modeling of iso- 1a) [Teller and Leverington, 2004]. Following residual meltwater and groundwater drain- ing, recreation, and power production, as static rebound rates in the Great Lakes Basin the retreat, the Great Lakes were then sup- age in the lowstands. well as water supply and wastewater dis- (GLB). The evidence includes newly dis- plied only by precipitation falling within the posal for municipalities. The overall range covered lowstand indicators in Lake Huron GLB, as at present. Explanation of the Lowstands of monthly water levels in all lakes during and Georgian Bay, such as submerged tree That the low- level lakes in the Huron and the past century has varied by less than stumps in situ and small lakes uplifted and Georgian Bay basins were closed hydrologi- Lakes without overflow, such as these 2.1 meters, and thus lake levels appear to isolated from the larger water bodies [Lewis cally is indicated by microfossil evidence lowstands in the GLB, can only be be relatively stable; yet even this amount of et al., 2005] and low- level erosion [Moore of brackish conditions (signifying excess explained by a dry climate in which water variation causes economic stress. et al., 1994]. evaporation) and a pause in outlet basin lost through evaporation exceeded water The interplay of three air masses (Fig- This body of evidence now confirms that sedimentation (suggesting cessation of river gained from direct precipitation and catch- ure 1c) currently controls climate and water lowstands occurred approximately from outflow). A lowstand also occurred in the ment runoff. The dry regional climate that levels in the Great Lakes watershed; most 7900 to 7500 radio carbon (8770–8300 cali- Erie basin at the same time, as indicated by forced the lakes into hydrologic closure brated) years B.P. in the Michigan, Huron, a submerged beach, while a shallow- water must have been substantially drier than and Georgian Bay basins (Figure 2a) [Lewis environment in Lake Ontario [Duthie et al., the present climate. Hydrologic model- BY C. F. MI C HAEL LEWIS , JOHN W. KING , STE F AN et al., 2005, 2007]. These hydrologically 1996] suggests a correlative lowstand in that ing of the present lakes shows that cur- M. BLAS C O , GREGORY R. BROO K S , JOHN P. closed lakes formed when water supply to basin as well. Acoustic profiling data show rent mean annual precipitation would have COA K LEY , THO M AS E. CROLEY II, DAVI D L DETT M AN , the GLB was greatly diminished by north- that submerged beaches of low- level lakes to decrease by about 25% in the Superior THO M AS W. D. ED WAR D S , CLI ff OR D W. HEIL JR., ward retreat of the Laurentide Ice Sheet. The also exist in the Superior basin [Wattrus, basin and by about 42% in the Ontario J. BRA df OR D HU B ENY , KATHLEEN R. LAIR D , retreat allowed discharge from Glacial Lake 2007]. A partial reconstruction of lowstands basin, in conjunction with a 5ºC mean tem- JOHN H. MCAN D REWS , FRAN C INE M. G. MCCARTHY , Agassiz to bypass the GLB into Glacial Lake is shown in Figure 2b; lowstand recon- perature increase, to achieve lake closure BAR B ARA E. ME D IOLI , THEO D ORE C. MOORE JR. Ojibway and drain via the Ottawa River val- struction is part of ongoing research. This [Croley and Lewis, 2006]. Paleoclimate sim- DAVI D K. REA , AN D ALISON J. SM ITH ley directly to the St. Lawrence River (Figure research also includes the assessment of ulations and reconstructions using pollen [Bartlein et al., 1998] and stable isotopes [Edwards et al., 1996] indicate that climate in the GLB (Figure 2c) was drier than pres- ent at 7900 radiocarbon (8770 calibrated) years B.P. Termination of the lowstand epi- sode about 7500 radiocarbon (8300 cali- brated) years B.P. coincides with the onset of a wetter climate as atmospheric circula- tion adjusted to the rapidly diminishing ice sheet [Dean et al., 2002] and moist air mass incursions from the Gulf of Mexico became more frequent. The discovery that the Great Lakes entered a low- level phase without having connecting rivers during the early Holo- cene dry period demonstrates the sensitivity of the lakes to climate change. The closed lakes of this phase occurred when the Great Lakes entered their present nonglacial state. Thus, the closed lakes afford a valuable example of past, high- amplitude, climate- driven hydrologic variation upon which an Fig. 1. (a) Location of the Great Lakes (blue) in eastern North America. Glacial Lake Agassiz (labeled A) is shown ~8000 14C (~8890 calibrated) improved assessment of lake- level sensitivity years before present (B.P.) when ice retreat caused its overflow drainage to switch from the Superior basin of the Great Lakes (red arrow) to Gla- in response to future climates can be based. cial Lake Ojibway (O) and the Ottawa River valley (black arrow). (b) The Laurentian Great Lakes and their watershed. (c) Major airstreams in North America with most water supplied to the Great Lakes by the moist air (tropical) from Gulf of Mexico [Bryson and Hare, 1974]. Laurentian Great Lakes cont. on page 542 541 EOS VOLUME 89 NUMBER 52 23 DECEMBER 2008 Hough, J. L. (1962), Lake Stanley, a low stage of Wattrus, N. J. (2007), Evidence of drowned paleo- Laurentian Great Lakes Lake Huron indicated by bottom sediments, shorelines in western Lake Superior, paper cont. from page 541 Geol. Soc. Am. Bull., 73, 613–620. presented at the 50th Annual Conference of the Larson, G., and R. Schaetzl (2001), Origin and International Association for Great Lakes Research, evolution of the Great Lakes, J. Great Lakes Res., Penn. State Univ., University Park, 28 May to 1 June. Acknowledgments parisons with paleoenvironmental data, Quat. 27, 518–546. Sci. Rev., 17, 549–585. Lewis, C. F. M., S. M. Blasco, and P. L. Gareau We are grateful to P. F. Karrow (University Bryson, R. A., and R. K. Hare (1974), The climate (2005), Glacial isostatic adjustment of the Lau- Author Information of North America, in of Waterloo), D. L. Forbes and S. St. George Climates of North America, rentian Great Lakes basin: Using the empirical edited by R.
Load more

Recommended publications
  • Varve-Related Publications in Alphabetical Order (Version 15 March 2015) Please Report Additional References, Updates, Errors Etc
    Varve-Related Publications in Alphabetical Order (version 15 March 2015) Please report additional references, updates, errors etc. to Arndt Schimmelmann ([email protected]) Abril JM, Brunskill GJ (2014) Evidence that excess 210Pb flux varies with sediment accumulation rate and implications for dating recent sediments. Journal of Paleolimnology 52, 121-137. http://dx.doi.org/10.1007/s10933-014-9782-6; statistical analysis of radiometric dating of 10 annually laminated sediment cores from aquatic systems, constant rate of supply (CRS) model. Abu-Jaber NS, Al-Bataina BA, Jawad Ali A (1997) Radiochemistry of sediments from the southern Dead Sea, Jordan. Environmental Geology 32 (4), 281-284. http://dx.doi.org/10.1007/s002540050218; Dimona, Jordan, gamma spectroscopy, lead-210, no anthropogenic contamination, calculated sedimentation rate agrees with varve record. Addison JA, Finney BP, Jaeger JM, Stoner JS, Norris RN, Hangsterfer A (2012) Examining Gulf of Alaska marine paleoclimate at seasonal to decadal timescales. In: (Besonen MR, ed.) Second Workshop of the PAGES Varves Working Group, Program and Abstracts, 17-19 March 2011, Corpus Christi, Texas, USA, 15-21. http://www.pages.unibe.ch/download/docs/working_groups/vwg/2011_2nd_VWG_workshop_programs_and_abstracts.pdf; ca. 60 cm marine sediment core from Deep Inlet in southeast Alaska, CT scan, XRF scanning, suspected varves, 1972 earthquake and tsunami caused turbidite with scouring and erosion. Addison JA, Finney BP, Jaeger JM, Stoner JS, Norris RD, Hangsterfer A (2013) Integrating satellite observations and modern climate measurements with the recent sedimentary record: An example from Southeast Alaska. Journal of Geophysical Research: Oceans 118 (7), 3444-3461. http://dx.doi.org/10.1002/jgrc.20243; Gulf of Alaska, paleoproductivity, scanning XRF, Pacific Decadal Oscillation PDO, fjord, 137Cs, 210Pb, geochronometry, three-dimensional computed tomography, discontinuous event-based marine varve chronology spans AD ∼1940–1981, Br/Cl ratios reflect changes in marine organic matter accumulation.
    [Show full text]
  • Bildnachweis
    Bildnachweis Im Bildnachweis verwendete Abkürzungen: With permission from the Geological Society of Ame- rica l – links; m – Mitte; o – oben; r – rechts; u – unten 4.65; 6.52; 6.183; 8.7 Bilder ohne Nachweisangaben stammen vom Autor. Die Autoren der Bildquellen werden in den Bildunterschriften With permission from the Society for Sedimentary genannt; die bibliographischen Angaben sind in der Literaturlis- Geology (SEPM) te aufgeführt. Viele Autoren/Autorinnen und Verlage/Institutio- 6.2ul; 6.14; 6.16 nen haben ihre Einwilligung zur Reproduktion von Abbildungen gegeben. Dafür sei hier herzlich gedankt. Für die nachfolgend With permission from the American Association for aufgeführten Abbildungen haben ihre Zustimmung gegeben: the Advancement of Science (AAAS) Box Eisbohrkerne Dr; 2.8l; 2.8r; 2.13u; 2.29; 2.38l; Box Die With permission from Elsevier Hockey-Stick-Diskussion B; 4.65l; 4.53; 4.88mr; Box Tuning 2.64; 3.5; 4.6; 4.9; 4.16l; 4.22ol; 4.23; 4.40o; 4.40u; 4.50; E; 5.21l; 5.49; 5.57; 5.58u; 5.61; 5.64l; 5.64r; 5.68; 5.86; 4.70ul; 4.70ur; 4.86; 4.88ul; Box Tuning A; 4.95; 4.96; 4.97; 5.99; 5.100l; 5.100r; 5.118; 5.119; 5.123; 5.125; 5.141; 5.158r; 4.98; 5.12; 5.14r; 5.23ol; 5.24l; 5.24r; 5.25; 5.54r; 5.55; 5.56; 5.167l; 5.167r; 5.177m; 5.177u; 5.180; 6.43r; 6.86; 6.99l; 6.99r; 5.65; 5.67; 5.70; 5.71o; 5.71ul; 5.71um; 5.72; 5.73; 5.77l; 5.79o; 6.144; 6.145; 6.148; 6.149; 6.160; 6.162; 7.18; 7.19u; 7.38; 5.80; 5.82; 5.88; 5.94; 5.94ul; 5.95; 5.108l; 5.111l; 5.116; 5.117; 7.40ur; 8.19; 9.9; 9.16; 9.17; 10.8 5.126; 5.128u; 5.147o; 5.147u;
    [Show full text]
  • 8 Ka Lake Stanley Lowstand on the Alpena‐
    Research Article Archaeological Landscapes during the 10–8 ka Lake Stanley Lowstand on the Alpena-Amberley Ridge, Lake Huron Elizabeth Sonnenburg1,* and John O’Shea2 1Stantec Consulting Ltd., Ontario, Canada 2Museum of Anthropological Archaeology, University of Michigan, Ann Arbor, Michigan, USA Correspondence Archaeologists have long been interested in the Lake Stanley lowstand event *Corresponding author; E-mail: (10–8 ka) in the Lake Huron basin, as archaeological sites from the Late Pale- [email protected] oindian/Early Archaic cultural periods were inundated by subsequent high wa- Received ter levels. Recent archaeological and paleoenvironmental investigations of this 15 January 2015 submerged landscape have documented stone structures that were likely uti- Revised lized for caribou hunting by these cultural groups during the late Lake Stanley 17 April 2016 lowstand phase of Lake Huron. In 2011 and 2012, a total of 67 core, sediment, Accepted and rock samples were collected in a 50 km2 area by divers and a ponar sam- 20 April 2016 pler deployed from a survey vessel. These samples were analyzed for sediment Scientific editing by Rolfe Mandel size, sorting, morphology and source, organic and carbonate content, testate amoebae, and organic materials. A series of indicators, including distinct mi- Published online in Wiley Online Library crofossil assemblages (such as species only found in sphagnum moss and boggy (wileyonlinelibrary.com). arctic ponds), rooted trees (tamarack and spruce), and charcoal (ca. 8–9000 yr old) reveal a series of microenvironments that are consistent with a subarctic doi 10.1002/gea.21590 climate. The analysis of the Alpena-Amberley Ridge provides a detailed pic- ture of the environment exploited by ancient peoples during the Lake Stanley lowstand period.
    [Show full text]
  • Geomorphic and Sedimentological History of the Central Lake Agassiz Basin
    Electronic Capture, 2008 The PDF file from which this document was printed was generated by scanning an original copy of the publication. Because the capture method used was 'Searchable Image (Exact)', it was not possible to proofread the resulting file to remove errors resulting from the capture process. Users should therefore verify critical information in an original copy of the publication. Recommended citation: J.T. Teller, L.H. Thorleifson, G. Matile and W.C. Brisbin, 1996. Sedimentology, Geomorphology and History of the Central Lake Agassiz Basin Field Trip Guidebook B2; Geological Association of CanadalMineralogical Association of Canada Annual Meeting, Winnipeg, Manitoba, May 27-29, 1996. © 1996: This book, orportions ofit, may not be reproduced in any form without written permission ofthe Geological Association ofCanada, Winnipeg Section. Additional copies can be purchased from the Geological Association of Canada, Winnipeg Section. Details are given on the back cover. SEDIMENTOLOGY, GEOMORPHOLOGY, AND HISTORY OF THE CENTRAL LAKE AGASSIZ BASIN TABLE OF CONTENTS The Winnipeg Area 1 General Introduction to Lake Agassiz 4 DAY 1: Winnipeg to Delta Marsh Field Station 6 STOP 1: Delta Marsh Field Station. ...................... .. 10 DAY2: Delta Marsh Field Station to Brandon to Bruxelles, Return En Route to Next Stop 14 STOP 2: Campbell Beach Ridge at Arden 14 En Route to Next Stop 18 STOP 3: Distal Sediments of Assiniboine Fan-Delta 18 En Route to Next Stop 19 STOP 4: Flood Gravels at Head of Assiniboine Fan-Delta 24 En Route to Next Stop 24 STOP 5: Stott Buffalo Jump and Assiniboine Spillway - LUNCH 28 En Route to Next Stop 28 STOP 6: Spruce Woods 29 En Route to Next Stop 31 STOP 7: Bruxelles Glaciotectonic Cut 34 STOP 8: Pembina Spillway View 34 DAY 3: Delta Marsh Field Station to Latimer Gully to Winnipeg En Route to Next Stop 36 STOP 9: Distal Fan Sediment , 36 STOP 10: Valley Fill Sediments (Latimer Gully) 36 STOP 11: Deep Basin Landforms of Lake Agassiz 42 References Cited 49 Appendix "Review of Lake Agassiz history" (L.H.
    [Show full text]
  • CHAPITRE V SYNTHÈSE ET CONCLUSION 5.1 Les Grands
    CHAPITRE V SYNTHÈSE ET CONCLUSION 5.1 Les grands constats La présente étude permet de jeter les bases en vue du développement d’une gestion adaptée aux dépôts granulaires (eskers) de l’Abitibi-Témiscamingue et du sud de la Baie-James. Ces dépôts renferment 10 610 millions de m 3 (10,6 km 3) de sables et graviers pour l’ensemble de la région. Il est important de bien saisir que ce volume représente une valeur minimale due à l’enfouissement de la base des eskers sous des sédiments à grains fins. Par contre, la partie des eskers qui affleure comprend le noyau grossier des eskers dans lequel la majorité des bancs d’emprunt sont situés. Les travaux de Kinnumen et al . (2006) ont estimé que les eskers sont constitués généralement de 25 % de graviers et de 75 % de sables; en ce sens, le volume de graviers, principale granulométrie d’intérêt économique, serait de 2 650 millions de m 3. Le volume total de dépôts granulaires de l’Abitibi-Témiscamingue et du sud de la Baie-James est loin d’être complètement exploité. Seulement une petite fraction est présentement prélevée. Toutefois, la disparité dans les volumes contenus dans les MRC (voir tableau 3.1) crée des problématiques de gestion différentes pour chacune. On retrouve minimalement 3 105 millions de m 3 de sables et graviers dans la MRC de La Vallée-de-l’Or, 2 503 millions de m 3 dans le sud la Baie-James, 1 950 millions de m 3 dans la MRC d’Abitibi, 1 630 millions de m 3 dans la MRC de Témiscamingue, 1 279 millions de m 3 dans la Ville de Rouyn-Noranda et 143 millions de m 3 dans la MRC d’Abitibi-Ouest.
    [Show full text]
  • Population Genetic Structure and Life History Variability in Oncorhynchus Nerka from the Snake River Basin
    University of Nebraska - Lincoln DigitalCommons@University of Nebraska - Lincoln Publications, Agencies and Staff of the U.S. Department of Commerce U.S. Department of Commerce 2011 Population Genetic Structure and Life History Variability in Oncorhynchus nerka from the Snake River Basin Robin Waples NOAA, [email protected] Paul B. Aebersold Northwest Fisheries Science Center Gary A. Winans Northwest Fisheries Science Center, [email protected] Follow this and additional works at: https://digitalcommons.unl.edu/usdeptcommercepub Waples, Robin; Aebersold, Paul B.; and Winans, Gary A., "Population Genetic Structure and Life History Variability in Oncorhynchus nerka from the Snake River Basin" (2011). Publications, Agencies and Staff of the U.S. Department of Commerce. 478. https://digitalcommons.unl.edu/usdeptcommercepub/478 This Article is brought to you for free and open access by the U.S. Department of Commerce at DigitalCommons@University of Nebraska - Lincoln. It has been accepted for inclusion in Publications, Agencies and Staff of the U.S. Department of Commerce by an authorized administrator of DigitalCommons@University of Nebraska - Lincoln. Transactions of the American Fisheries Society 140:716–733, 2011 American Fisheries Society 2011 ISSN: 0002-8487 print / 1548-8659 online DOI: 10.1080/00028487.2011.584491 SPECIAL SECTION: GENETIC ADAPTATION Population Genetic Structure and Life History Variability in Oncorhynchus nerka from the Snake River Basin Robin S. Waples,* Paul B. Aebersold, and Gary A. Winans NOAA Fisheries Service, Northwest Fisheries Science Center, 2725 Montlake Boulevard East, Seattle, Washington 98112, USA Abstract We used the variation at 64 allozyme loci to examine genetic relationships among 32 samples of sockeye salmon Oncorhynchus nerka and kokanee (resident sockeye salmon) from the Snake River basin and other North American locations.
    [Show full text]
  • On the Reconstruction of Palaeo-Ice Sheets : Recent Advances and Future Challenges.', Quaternary Science Reviews., 125
    Durham Research Online Deposited in DRO: 19 October 2015 Version of attached le: Accepted Version Peer-review status of attached le: Peer-reviewed Citation for published item: Stokes, C.R. and Tarasov, L. and Blomdin, R. and Cronin, T.M. and Fisher, T.G. and Gyllencreutz, R. and H¤attestrand,C. and Heyman, J. and Hindmarsh, R.C.A. and Hughes, A.L.C. and Jakobsson, M. and Kirchner, N. and Livingstone, S.J. and Margold, M. and Murton, J.B. and Noormets, R. and Peltier, W.R. and Peteet, D.M. and Piper, D.J.W. and Preusser, F. and Renssen, H. and Roberts, D.H. and Roche, D.M. and Saint-Ange, F. and Stroeven, A.P. and Teller, J.T. (2015) 'On the reconstruction of palaeo-ice sheets : recent advances and future challenges.', Quaternary science reviews., 125 . pp. 15-49. Further information on publisher's website: http://dx.doi.org/10.1016/j.quascirev.2015.07.016 Publisher's copyright statement: c 2015 This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/ Additional information: Use policy The full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that: • a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.
    [Show full text]
  • Evidence for Synchronous Global Climatic Events: Cosmogenic Exposure Ages of Glaciations
    Chapter 2 Evidence for Synchronous Global Climatic Events: Cosmogenic Exposure Ages of Glaciations Don J. Easterbrook *, John Gosse y, Cody Sherard z, Ed Evenson ** and Robert Finkel yy * Department of Geology, Western Washington University, Bellingham, WA 98225, USA, y Dalhousie University, Halifax, Nova Scotia, Canada B3H 4R2, z Department of Geology, Western Washington University, Bellingham, WA 98225, USA, ** Earth and Environmental Sciences Department, Bethlehem, PA 18015, USA, yy Lawrence Livermore National Laboratory, Livermore, CA 94550 Chapter Outline 1. Introduction 53 2.2. Global LGM Moraines 66 2. Late Pleistocene Climate 2.3. Global Younger Oscillations Recorded by Dryas Moraines 72 Glaciers 54 3. Conclusions 83 2.1. Sawtooth Mts. Acknowledgments 83 Moraine Sequences 56 1. INTRODUCTION Why is knowledge of short-term sensitivity of glaciers to climatic/oceanic changes important? Despite three decades of research on abrupt climate changes, such as the Younger Dryas (YD) event, the geological community is only now arriving at a consensus about its global extent, but has not established an unequivocal cause or a mechanism of global glacial response to rapid climate changes. At present, although Greenland ice cores have allowed the development of highly precise 18O curves, we cannot adequately explain the cause of abrupt onset and ending of global climatic reversals. In view of present global warming, understanding the cause of climate change is critically Evidence-Based Climate Science. DOI: 10.1016/B978-0-12-385956-3.10002-6 Copyright Ó 2011 Elsevier Inc. All rights reserved. 53 54 PART j I Geologic Perspectives important to human populationsdthe initiation and cessation of the YD ice age were both completed within a human generation.
    [Show full text]
  • Postglacial Water Levels in the Great Lakes Region in Relation to Holocene Climate Change: Thecamoebian and Palynological Evidence
    Postglacial Water Levels in the Great Lakes Region in Relation to Holocene Climate Change: Thecamoebian and Palynological Evidence by Adam Patrick Sarvis, B.Sc. A thesis submitted to the Department of Earth Sciences in partial fulfillment of the requirements for the degree of Master of Science December, 2000 Brock University St. Catharines, Ontario © Adam Patrick Sarvis, 2000 Abstract Various lake phases have developed in the upper Great Lakes in response to isostatic adjustment and changes in water supply since the retreat of the Laurentide Ice Sheet. Georgian Bay experienced a lowstand that caused a basin wide unconformity approximately 7,500 years ago that cannot be explained by geological events. Thecamoebians are shelled protozoans abundant in freshwater environments and they are generally more sensitive to changing environmental conditions than the surrounding vegetation. Thecamoebians can be used to reconstruct the paleolimnology. The abundance of thecamoebians belonging to the genus Centropyxis, which are known to tolerate slightly brackish conditions (i.e. high concentrations of ions) records highly evaporative conditions in a closed basin. During the warmer interval (9000 to 700 yBP), the Centropyxis - dominated population diminishes and is replaced by an abundant and diverse Difflugia dominate population. Historical climate records from Tobermory and Midland, Ontario were correlated with the Lake Huron water level curve. The fossil pollen record and comparison with modem analogues allowed a paleo-water budget to be calculated for Georgian Bay. Transfer function analysis of fossil pollen data from Georgian Bay records cold, dry winters similar to modem day Minneapolis, Minnesota. Drier climates around this time are also recorded in bog environments in Southem Ontario - the drying of Lake Tonawanda and inception of paludification in Willoughby Bog, for instance, dates around 7,000 years ago.
    [Show full text]
  • LAKES of the HURON BASIN: THEIR RECORD of RUNOFF from the LAURENTIDE ICE Sheetq[
    Quaterna~ ScienceReviews, Vol. 13, pp. 891-922, 1994. t Pergamon Copyright © 1995 Elsevier Science Ltd. Printed in Great Britain. All rights reserved. 0277-3791/94 $26.00 0277-3791 (94)00126-X LAKES OF THE HURON BASIN: THEIR RECORD OF RUNOFF FROM THE LAURENTIDE ICE SHEETq[ C.F. MICHAEL LEWIS,* THEODORE C. MOORE, JR,t~: DAVID K. REA, DAVID L. DETTMAN,$ ALISON M. SMITH§ and LARRY A. MAYERII *Geological Survey of Canada, Box 1006, Dartmouth, N.S., Canada B2 Y 4A2 tCenter for Great Lakes and Aquatic Sciences, University of Michigan, Ann Arbor, MI 48109, U.S.A. ::Department of Geological Sciences, University of Michigan, Ann Arbor, MI 48109, U.S.A. §Department of Geology, Kent State University, Kent, 0H44242, U.S.A. IIDepartment of Geomatics and Survey Engineering, University of New Brunswick, Fredericton, N.B., Canada E3B 5A3 Abstract--The 189'000 km2 Hur°n basin is central in the catchment area °f the present Q S R Lanrentian Great Lakes that now drain via the St. Lawrence River to the North Atlantic Ocean. During deglaciation from 21-7.5 ka BP, and owing to the interactions of ice margin positions, crustal rebound and regional topography, this basin was much more widely connected hydrologi- cally, draining by various routes to the Gulf of Mexico and Atlantic Ocean, and receiving over- ~ flows from lakes impounded north and west of the Great Lakes-Hudson Bay drainage divide. /~ Early ice-marginal lakes formed by impoundment between the Laurentide Ice Sheet and the southern margin of the basin during recessions to interstadial positions at 15.5 and 13.2 ka BE In ~ ~i each of these recessions, lake drainage was initially southward to the Mississippi River and Gulf of ~ Mexico.
    [Show full text]
  • Glacial Lakes Around Michigan
    The Glacial Lakes around Michigan By William R. Farrand, University of Michigan Bulletin 4, revised 1988 Geological Survey Division Michigan Department of Environmental Quality Bulletin 4 - Glacial Lakes Around Michigan By William R. Farrand, University of Michigan, 1967 revised 1998 Illustrated by Kathline Clahassey, University of Michigan Published by Michigan Department of Environmental Quality. Geological Survey Division Contents Preface............................................................................................................................................ 3 Abstract........................................................................................................................................... 3 Introduction ..................................................................................................................................... 4 Was There A Glacier?..................................................................................................................... 4 Figure 1: The modem Great Lakes have a water surface area greater than 95,000 square miles, a total drainage area of about 295,000 square miles, and a shore line 8,300 miles long. ................................................................................................4 Figure 2: Features originating at a glacier front occur in a definite order. ...................................................................................5 Figure 3: Landforms of continental glaciation are unmistakable. Compare with figure 2 ............................................................5
    [Show full text]
  • A 9,000-Year-Old Caribou Hunting Structure Beneath Lake Huron
    A 9,000-year-old caribou hunting structure beneath Lake Huron John M. O’Sheaa,1, Ashley K. Lemkea, Elizabeth P. Sonnenburga, Robert G. Reynoldsb, and Brian D. Abbottc aMuseum of Anthropological Archaeology, University of Michigan, Ann Arbor, MI 48109; bDepartment of Computer Science, Wayne State University, Detroit, MI 48202; and cNautilus Marine Group International, LLC, Haslett, MI 48840 Edited by Bruce D. Smith, National Museum of Natural History, Smithsonian Institution, Washington, DC, and approved April 8, 2014 (received for review March 7, 2014) Some of the most pivotal questions in human history necessitate dates from 8,900–8,640 cal B.P., whereas charcoal recovered the investigation of archaeological sites that are now under water. from the middle of a circle of small stones yielded a date of 9,020 Nine thousand years ago, the Alpena-Amberley Ridge (AAR) be- cal B.P. (Table S2). The environment that emerges from these neath modern Lake Huron was a dry land corridor that connected studies is one that would have been ideal for migrating caribou northeast Michigan to southern Ontario. The newly discovered and for their human pursuers. Drop 45 Drive Lane is the most complex hunting structure found Humans and caribou have a long history of interaction, dating to date beneath the Great Lakes. The site and its associated arti- back to at least the Middle Paleolithic (8, 9). Over time, caribou facts provide unprecedented insight into the social and seasonal hunters and herders became aware of the tendency of caribou, organization of prehistoric caribou hunting. When combined with like many ungulates, to follow linear features (10).
    [Show full text]