Hostname: page-component-78c5997874-xbtfd Total loading time: 0 Render date: 2024-11-14T05:08:15.117Z Has data issue: false hasContentIssue false
  • English
  • Français

Extending the Place Glacier mass-balance record to AD 1585, using tree rings and wood density

Published online by Cambridge University Press:  20 January 2017

Lisa J. Wood ,
Dan J. Smith  and
Michael N. Demuth
Lisa J. Wood
Affiliation:
University of Victoria Tree-Ring Laboratory, Department of Geography, University of Victoria, Victoria, British Columbia V8W 3R4, Canada
Dan J. Smith*
Affiliation:
University of Victoria Tree-Ring Laboratory, Department of Geography, University of Victoria, Victoria, British Columbia V8W 3R4, Canada
Michael N. Demuth
Affiliation:
Glaciology Section, Geological Survey of Canada, Natural Resources Canada, 601 Booth Street, Ottawa, Ontario K1A 0E8, Canada
*
Corresponding author. Tel.: + 1 250 721 7328. E-mail address:smith@uvic.ca (D. J. Smith).
Get access Rights & Permissions [Opens in a new window]

Abstract

Recognizing that climate influences both annual tree-ring growth and glacier mass balance, changes in the mass balance of Place Glacier, British Columbia, were documented from increment core records. Annually resolved ring-width (RW), maximum (MXD), and mean density (MD) chronologies were developed from Engelmann spruce and Douglas-fir trees sampled at sites within the surrounding region. A snowpack record dating to AD 1730 was reconstructed using a multivariate regression of spruce MD and fir RW chronologies. Spruce MXD and RW chronologies were used to reconstruct winter mass balance (Bw) for Place Glacier to AD 1585. Summer mass balance (Bs) was reconstructed using the RW chronology from spruce, and net balance was calculated from Bw and Bs. The reconstructions provide insight into the changes that snowpack and mass balance have undergone in the last 400 years, as well as identifying relationships to air temperature and circulation indices in southern British Columbia. These changes are consistent with other regional mass-balance reconstructions and indicate that the persistent weather systems characterizing large scale climate-forcing mechanisms play a significant glaciological role in this region. A comparison to dated moraine surfaces in the surrounding region substantiates that the mass-balance shifts recorded in the proxy data are evident in the response of glaciers throughout the region.

Keywords

DendroclimatologyGlacier mass balanceTree ringsWood densityPlace Glacier
Type
Research Article
Information
Quaternary Research , Volume 76 , Issue 3 , November 2011 , pp. 305 - 313
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Allen, S.M., and Smith, D.J. Late Holocene glacial activity of Bridge Glacier, British Columbia Coast Mountains. Canadian Journal of Earth Sciences 44, (2007). 17531773.Google Scholar
Arendt, A., Walsh, J., and Harrison, W. Changes of glaciers and climate in northwestern North America during the late twentieth century. Journal of Climate 22, (2009). 41174134.CrossRefGoogle Scholar
Bitz, C.M., and Battisti, D.S. Interannual to decadal variability in climate and the glacier mass balance in Washington, Western Canada, and Alaska. The American Meteorological Society 12, (1999). 31813196.Google Scholar
Blasing, T.J., Duvick, D.N., and West, D.C. Dendroclimatic calibration and verification using regionally averaged and single station precipitation data. Tree-Ring Bulletin. 41, (1981). 3743.Google Scholar
Brambor, T., Clark, W.R., and Golder, M. Understanding interaction models: improving empirical analysis. Political Analysis 14, (2006). 6382.CrossRefGoogle Scholar
Briffa, K.R., Jones, P.D., and Schweingruber, F.H. Summer temperature patterns over Europe: a reconstruction from 1750 A.D. based on maximum latewood density indices of conifers. Quaternary Research 30, (1988). 3652.CrossRefGoogle Scholar
Briffa, K.R., Jones, P.D., and Schweingruber, F.H. Tree-ring density reconstructions of summer temperature patterns across western north America since 1600. Journal of Climate 5, (1992). 735754.2.0.CO;2>CrossRefGoogle Scholar
Briffa, K.R., Osborn, T.J., Schweingruber, F.H., Jones, P.D., Shiyatov, S.G., and Vaganov, E.A. Tree-ring width and density data around the Northern Hemisphere: Part 1, local and regional climate signals. The Holocene 12, (2002). 737757.Google Scholar
Conkey, L.E. Red spruce tree-ring widths and densities in eastern North America as indicators of past climate. Quaternary Research 26, (1986). 232243.CrossRefGoogle Scholar
Cook, E.R. (1985). A Time-Series Analysis Approach to Tree-Ring Standardization . Ph.D. Unpublished Thesis. University of Arizona, : Tucson.Google Scholar
Cook, E.R., and Holmes, R.L. Users manual for the program ARSTAN. Holmes, R.L., Adams, R.K., and Fritts, H.C. Tree-ring Chronologies of Western North America: California, Eastern Oregon, and Northern Great Basin with Procedures Used in the Chronology Development Work Including Users Manuals for Computer Programs COFECHA and ARSTAN. Chronology Series VI (1986). Laboratory of Tree-ring Research, The University of Arizona, Tucson. 5065.Google Scholar
Cook, E.R., and Kairiukstis, L.A. Methods of Dendrochronology: Applications in the Environmental Sciences. (1990). Kluwer, Dordrecht.Google Scholar
D'Arrigo, R.D., Jacoby, G.C., and Free, R.M. Tree-ring width and maximum latewood density at the North American tree line: parameters of climatic change. Canadian Journal of Forest Research 22, (1992). 12901296.CrossRefGoogle Scholar
Davi, N.K., D'Arrigo, R.D., Jacoby, J.G., Buckley, B., and Kobayashi, O. Warm-season annual to decadal temperature variability for Hokkaido, Japan, inferred from maximum latewood density (AD 1557–1990) and ring width (AD 1532–1990). Climatic Change 52, (2002). 210217.Google Scholar
Déry, S.J., Hernández-Henríquez, M.A., Burford, J.E., and Wood, E.F. Observational evidence of an intensifying hydrological cycle in northern Canada. Geophysical Research Letters 36, (2009). L13402 doi:http://dx.doi.org/10.1029/2009GL038852 CrossRefGoogle Scholar
Demuth, M.N., Pinard, V., Pietroniro, A., Luckman, B.H., Hopkinson, C., Dornes, P., and Comeau, L. Recent and past-century variations in the glacier resources of the Canadian Rocky Mountains–Nelson River System. Terra Glacialis - Special Issue: Mountain Glaciers and Climate Changes in the Last Century. (2008). 2752.Google Scholar
Demuth, M.N., Sekerka, J., Bertollo, S., and Shea, J. Glacier mass balance observations for Place Glacier, British Columbia, Canada (updated to 2007). Spatially Referenced Data Set Contribution to the National Glacier-Climate Observing System, State and Evolution of Canada's Glaciers. (2009). Geological Survey of Canada, Ottawa. http://pathways.geosemantica.net/WSHome.aspx?ws=NGP_SECG&locale=en-CA Retrieved on 2008-03-09 Google Scholar
Dyurgerov, M. Glacier mass balance and regime measurements and analysis, 1945–2003. Meier, M., and Armstrong, R. (2002). Institute of Arctic and Alpine Research, University of Colorado, Boulder, CO. Distributed by National Snow and Ice Data Center, Boulder, CO. Updated 2005. Google Scholar
Fleming, S.W., Whitfield, P.H., Moore, R.D., and Quilty, E.J. Regime-dependent streamflow sensitivities to Pacific climate modes across the Georgia–Puget transboundary ecoregion. Hydrological Processes 21, (2007). 32643287.Google Scholar
Flower, A., and Smith, D.J. A dendroclimatic reconstruction of June-July mean temperature in the Northern Canadian Rocky Mountains. Dendrochonolgia 29, (2011). 5563.CrossRefGoogle Scholar
Fritts, H.C. Tree Rings and Climate. (1976). Academic Press, New York.Google Scholar
Fritts, H.C. PRECON Version 5.17B. (1999). Google Scholar
Grabner, M., Wimmer, R., Gierlinger, N., Evans, R., and Downes, G. Heartwood extractives in larch and effects on X-ray densitometry. Canadian Journal of Forest Research 35, (2005). 27812786.CrossRefGoogle Scholar
Gordon, G.A. Verification of dendroclimatic reconstructions. Hughes, M.K., Kelly, P.M., Pilcher, J.R., LaMarche, V.C. Jr. Climate from Tree Rings. (1982). Cambridge University Press, Cambridge. 5861.Google Scholar
Haygreen, J.G., and Bowyer, J.L. Forest Products and Wood Science. 3rd ed. (1996). Iowa State University Press, Ames, Iowa. 484 pp.Google Scholar
Holmes, R.L. Computer assisted quality control in tree-ring dating and measurement. Tree-Ring Bulletin 43, (1983). 6978.Google Scholar
Jensen, W.B. The origin of the Soxhlet extractor. Chemical Education Today 84, (2007). 19131914.Google Scholar
Koch, J. Improving age estimates for late Holocene glacial landforms using dendrochronology — some examples from Garibaldi Provincial Park, British Columbia. Quaternary Geochronology 4, (2009). 130139.Google Scholar
Koch, J., Clague, J.J., and Osborn, G.D. Glacier fluctuations during the past millennium in Garibaldi Provincial Park, southern Coast Mountains, British Columbia. Canadian Journal of Earth Science 44, (2007). 12151233.CrossRefGoogle Scholar
Koehler, L., and Smith, D.J. Late-Holocene glacial activity in Manatee Valley, southern Coast Mountains, British Columbia, Canada. Canadian Journal of Earth Sciences 48, (2011). 603618.Google Scholar
Larocque, S.J., and Smith, D.J. Little Ice Age glacial activity in the Mt Waddington area, British Columbia Coast Mountains, Canada. Canadian Journal of Earth Science 40, (2003). 14131436.CrossRefGoogle Scholar
Larocque, S.J., and Smith, D.J. A dendroclimatological reconstruction of climate since AD 1700 in the Mount Waddington area, British Columbia Coast Mountains, Canada. Dendrochronologia 22, (2005). 93106.Google Scholar
Larocque, S.J., and Smith, D.J. ‘Little Ice Age’ proxy glacier mass balance records reconstructed from tree rings in the Mount Waddington area, British Columbia Coast Mountains, Canada. The Holocene 15, (2005). 748757.CrossRefGoogle Scholar
Lewis, D., and Smith, D.J. Dendrochronological mass balance reconstruction, Strathcona Provincial Park, Vancouver Island, British Columbia, Canada. Arctic, Antarctic, and Alpine Research 36, (2004). 598606.Google Scholar
Lenz, O., Schar, E., and Schweingruber, F.H. Methodological problems relative to measurement density and width of growth rings by X-ray densitograms of wood. Holzforschung 30, (1976). 114123.CrossRefGoogle Scholar
Luckman, B.H., Briffa, K.H., Jones, P.D., and Schweingruber, F.H. Tree-ring based reconstruction of summer temperatures at the Columbia Icefield, Alberta, Canada, AD 1073–1983. The Holocene 7, (1997). 375389.Google Scholar
Mokievsky-Zubok, O., Ommanney, C.S.L., and Power, J. NHRI Glacier Mass Balance, 1964–1984 (Cordillera and Arctic). (1985). National Hydrology Research Institute, Inland Waters Directorate, Environment Canada, 1p. + 58 tables. Google Scholar
Mokievsky-Zubok, O., and Stanley, A.D. Canadian glaciers in the International Hydrological Decade Program, 1965–1974, No. 2. Place Glacier, British Columbia — Summary of Measurements. Scientific Series 69, (1976). 77 pp.Google Scholar
Moore, D., and Demuth, M. Mass balance and streamflow variability at Place Glacier, Canada, in relation to recent climate fluctuations. Hydrological Processes 15, (2001). 34733486.CrossRefGoogle Scholar
Moore, R.D., Fleming, S.W., Menounos, B., Wheate, R., Fountain, A., Stahl, K., Holm, K., and Jakob, M. Glacier change in western North America: influences on hydrology, geomorphic hazards and water quality. Hydrological Processes 23, (2009). 4261.Google Scholar
Munro, D.S., (2010). Personal communication.Google Scholar
Munro, D.S., and Marosz-Wantuch, M. Modeling ablation on Place Glacier, British Columbia, from glacier and off-glacier datasets. Arctic, Antarctic, and Alpine Research 41, (2009). 246256.Google Scholar
Nicolussi, K., and Patzelt, G. Reconstructing glacier history in Tyrol by means of tree-ring investigations. Zeitschrift fűr Gletscherkunde und Glazialgeologie 32, (1996). 207215.Google Scholar
Østrem, G. Mass balance studies on glaciers in western Canada, 1965. Geographical Bulletin 8, (1966). 81107.Google Scholar
Østrem, G. The transient snowline and glacier mass balance in southern British Columbia and Alberta. Geografiska Annaler 55A, (1973). 93106.Google Scholar
Parker, M.L. Improving tree-ring dating in Northern Canada by X-ray densitometry. Syesis 9, (1976). 163172.Google Scholar
Polge, H. The use of X-ray densitometry methods in dendrochronology. Tree-Ring Bulletin 30, (1970). 110.Google Scholar
Schiefer, E., Menounos, B., and Wheate, R. Recent volume loss of British Columbian glaciers, Canada. Geophysical Research Letters 34, (2007). L16503 http://dx.doi.org/10.1029/2007GL030780 Google Scholar
Schweingruber, F.H., Briffa, K.R., and Nogler, P. A tree-ring densiometric transect from Alaska to Labrador. International Journal of Biometeorology 37, (1993). 151169.Google Scholar
Schweingruber, F.H., Briffa, K.R., and Jones, P.D. Yearly maps of summer temperatures in Western Europe from A.D. 1750 to 1975 and western North America from 1600 to 1982. Vegetatio 92, (1991). 571.Google Scholar
Schweingruber, F.H. Radiodensitometry. Cook, E.R., and Kairiukstis, A. Methods of Dendrochronology. (1990). Kluwer Academic Publishers, Dordrecht, Netherlands. 5563.Google Scholar
Schweingruber, F.H., Fritts, H.C., Bräker, O.U., Drew, L.G., and Schär, E. The X-ray technique as applied to dendroclimatology. Tree-Ring Bulletin 38, (1978). 6191.Google Scholar
Shea, J.M., Moore, R.D., and Stahl, K. Derivation of melt factors from glacier mass-balance records in western Canada. Journal of Glaciology 55, (2009). 123130.Google Scholar
Stahl, K., Moore, R.D., and McKendry, I.G. The role of synoptic-scale circulation in the linkage between large-scale ocean-atmosphere indices and winter surface climate in British Columbia, Canada. International Journal of Climatology 26, (2006). 541560.CrossRefGoogle Scholar
Stokes, M.A., and Smiley, T.L. An Introduction to Tree-Ring Dating. (1968). University of Chicago Press, Chicago, Ill.Google Scholar
VanLooy, J.A., and Forster, R.R. Glacial changes of five southwest British Columbia icefields, Canada, mid-1980s to 1999. Journal of Glaciology 54, (2008). 469478.Google Scholar
Walters, R.A., and Meier, M.F. Variability of glaciers mass balances in western North America. Aspects of Climate Variability in the Pacific and Western Americas. Geophysical Monograph 55, (1989). American Geophysical. Union, 365374.Google Scholar
Watson, E., and Luckman, B.H. Tree-ring-based mass-balance estimates for the past 300 years at Peyto Glacier, Alberta, Canada. Quaternary Research 62, (2004). 918.CrossRefGoogle Scholar
Watson, E., Pederson, G.T., Luckman, B.H., and Fagre, D.B. Glacier mass balance in the northern U.S. and Canadian Rockies: paleo-perspectives and 20th century change. Orlove, B.S., Wiegandt, E., and Luckman, B.H. Darkening Peaks: Glacier Retreat, Science and Society. (2008). University of California Press, Berkeley, California. 141153.Google Scholar
Wimmer, R., and Grabner, M. A comparison of tree-ring features in Picea abies as correlated with climate. IAWA Journal 21, (2000). 403416.CrossRefGoogle Scholar
Youngblut, D., and Luckman, B. Maximum June-July temperatures in the southwest Yukon over the last 300 years reconstructed from tree rings. Dendrochonologia 25, (2008). 153166.Google Scholar