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Eigenvector Analysis of Reconstructed Holocene July Temperature Departures over Northern Canada

Published online by Cambridge University Press:  20 January 2017

John T. Andrews
Affiliation:
Department of Geological Sciences and Institute of Arctic and Alpine Research, University of Colorado, Boulder, Colorado 80309
Henry F. Diaz
Affiliation:
National Climatic Center, National Oceanic and Atmospheric Administration, Asheville, North Carolina 28801

Abstract

July temperatures for the past 6000 yr at 11 sites in northern Canada have been predicted by transfer-function equations. Normalized departures from the mean of each time series at 250-yr intervals are analyzed by principal component (eigenvector) analysis. An initial analysis included 9 sites and the first three principal components accounted for 85.7% of the variance. Maps of the loadings on the principal components show broad spatial coherence on all three components. Temporal coefficients (principal component scores) illustrate major regional and local midsummer temperature variations. An additional 2 sites were then included but the spatial pattern of the loadings remained essentially unchanged. A further test of this approach, with a view toward predicting paleoclimates of northern regions, was to use the spatial coefficients (loadings) to estimate the July temperature departures at an “unknown” site (Long Lake, Keewatin). This reconstruction compares favorably with an independent transfer-function reconstruction (Kay, 1979). Power spectrum analysis of the significant principal component scores (temperature departures) over the 6000 yr showed that the temporal fluctuations associated with the first three principal components follow a “red noise” spectrum, indicative of strong persistence in the reconstructed climatic records. The scores on the fourth principal component approximate a “white noise” spectrum. A peak in power between 2000 and 3000 yr occurs in the variance spectrum of the second principal component (significance 10%). We conclude that eigenvector analysis of Holocene paleoclimatic data has considerable power and may be useful for identifying regional and local climatic variations.

Type
Original Articles
Copyright
University of Washington

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References

Andrews, J.T., Davis, P.T., Mode, W.N., Nichols, H., Short, S.K. 1981. Relative departures in July temperatures in northern Canada for the past 6,000 yr. Nature (London) 289. 164167.CrossRefGoogle Scholar
Andrews, J.T., Mode, W.N., Davis, P.T. 1980. Holocene climate based on pollen transfer functions, eastern Canadian Arctic. Arctic and Alpine Research 12. 4164.Google Scholar
Andrews, J.T., Nichols, H. 1981. Modern pollen deposition and Holocene temperature reconstructions, Central Northern Canada. Arctic and Alpine Researchin pressGoogle Scholar
Bernabo, J.C. 1981. Quantitative estimates of temperature changes over the last 2700 years in Michigan based on pollen data. Quaternary Research 15. 143159.Google Scholar
Brown, J., Andrews, J.T. 1981 Influence of Short-Term Climatic Change on Permafrost Department of Energy Washington, D.Cin pressGoogle Scholar
Bryson, R.A., Irving, W.N., Larsen, J.A. 1965. Radiocarbon and soils evidence of former forest in the southern Canadian tundra. Science 147. 4648.Google Scholar
Bryson, R.A., Wendland, W.M., Ives, J.D., Andrews, J.T. 1969. Radiocarbon isochrones on the disintegration of the Laurentide Ice Sheet. Artic and Alpine Research 1. 114.Google Scholar
Davis, P.T. 1980. Late Holocene Glacial, Vegetational and Climatic History of Pangnirtung and Kingnait Fiord Area, Baffin Island, Canada. Ph.D. thesis University of Colorado Boulder.Google Scholar
Denton, G., Karlen, W. 1973. Holocene climatic variations, their pattern and possible cause. Quaternary Research 3. 155205.Google Scholar
Department of Energy. 1979 Summary of the Carbon Dioxide Effects Research and Assessment Program Department of Energy Washington, D.C.Google Scholar
Fritts, H.C., Blasing, T.J., Hayden, B.P., Kutzbach, J.E. 1971. Multivariate techniques for specifying tree-growth and climate relationships and for reconstructing anomalies in Paleoclimate. Journal of Applied Meteorology 10. 845864.Google Scholar
Gilman, D.L., Fuglister, F.J., Mitchell, J.M. Jr. 1963. On the power spectrum of “red noise”. Journal of Atmospheric Science 20. 182184.Google Scholar
Idso, S.B. 1980. The climatological significance of a doubling of earth's atmospheric carbon dioxide concentration. Science 207. 14621463.Google Scholar
Imbrie, J. 1980. The oceanic record of Quaternary climate: Orthogonal generalizations drawn from isotopic and biotic time series. Geological Society of America, Abstracts 12. 453 Google Scholar
Kay, P.A. 1979. Multivariate statistical estimates of Holocene vegetation and climate change, forest-tundra transition zone, N. W. T., Canada. Quaternary Research 11. 125140.Google Scholar
Kellogg, W.W. 1979. Influences of mankind on climate. Annual Review of Earth and Planetary Science 7. 6392.CrossRefGoogle Scholar
Kennett, J.P., Penrose, N., Leventer, A. 1980. High resolution Holocene paleoclimatology and stratigraphy, Orca Basin, Gulf of Mexico. Geological Society of America, Abstracts 12. 461 Google Scholar
Kidson, J.W. 1975. Eigenvector analysis of monthly mean surface data. Monthly Weather Review 103. 177186.2.0.CO;2>CrossRefGoogle Scholar
Kutzbach, J.E. 1967. Empirical eigenvectors of sea-level pressure, surface temperature and precipitation complexes over North America. Journal of Applied Meteorology 6. 791802.Google Scholar
Kutzbach, J.E. 1976. The nature of climate and climatic variations. Quaternary Research 6. 471480.Google Scholar
Kutzbach, J.E., Bryson, R.A. 1974. Variance spectrum of Holocene climate fluctuations in the North Atlantic sector. Journal of Atmospheric Science 31. 19581963.Google Scholar
LaMarche, V.C. Jr. 1973. Holocene climatic variations inferred from tree-line fluctuations in the White Mountains, California. Quaternary Research 3. 632660.CrossRefGoogle Scholar
Lamb, H.H. 1977 Climate: Past, Present, and Future Vol. 2 Methuen London.Google Scholar
Manabe, S., Stouffer, R.J. 1979. Climate sensitivity study: Mathematical model of global climate. Nature (London) 282. 491493.Google Scholar
McCulloch, D., Hopkins, D. 1966. Evidence for early recent warm interval in northeast Alaska. Geological Society of America Bulletin 77. 10891108.Google Scholar
Miller, P.C. 1981 Research Needed to Determine the Present Carbon Balance of Northern Ecosystems and the Potential Effect of Carbon Dioxide Induced Climate Change Department of Energy Washington, D.Cin pressGoogle Scholar
Mitchell, J.M. Jr. 1976. An overview of climatic variability and its causal mechanisms. Quaternary Research 6. 481494.Google Scholar
Mode, W.N. 1980. Quaternary Stratigraphy and Palynology of the Clyde Foreland, Baffin Island, N.W.T., Canada. Ph.D. thesis University of Colorado Boulder.Google Scholar
National Academy of Sciences. 1975 Understanding Climatic Change: A Program for Action National Academy of Sciences Washington, D.C.Google Scholar
Nichols, H. 1967. The postglacial history of vegetation and climate at Ennadai Lake, Keewatin, and Lynn Lake, Manitoba. Eiszeitalter und Gegenwart 18. 176197.Google Scholar
Nichols, H. 1975 Palynological and Paleoclimatological Study of the Late Quaternary Displacement of the Boreal Forest-Tundra Ecotone in Keewatin and MacKenzie, N.W.T., Canada University of Colorado BoulderINSTAAR Occasional Paper No. 15Google Scholar
Nichols, H., Kelly, P.M., Andrews, J.T. 1978. Holocene paleo-wind evidence from palynology in Baffin Island. Nature (London) 273. 140142.Google Scholar
Prest, V.K. 1969. Retreat of Wisconsin and recent ice in North America. Geological Survey of CanadaMap 1257AGoogle Scholar
Ritchie, J.C. 1980. Towards a Late-Quaternary vegetation paleoecology of the ice-free Corridor. Canadian Journal of Anthropology 1. 1528.Google Scholar
Ritchie, J.C., Hare, F.K. 1971. Late-Quaternary vegetation and climate near the Arctic tree line of northwestern North America. Quaternary Research 1. 331342.CrossRefGoogle Scholar
Short, S.K. 1978. Holocene Palynology in Labrador-Ungava: Climatic History and Cultural Change on the Central Coast. Ph.D. thesis University of Colorado Boulder.Google Scholar
Short, S.K., Jacobs, J.D. 1981. Palynology in relation to vegetation and climate in Burton Bay-Tarr Inlet, Baffin Island. Canadian Journal of Earth Sciencesin pressGoogle Scholar
Suess, H.E. 1971. Climatic changes and the atmospheric radiocarbon level. Paleogeography, Paleoclimatology, & Paleoecology 10. 199202.Google Scholar
Walker, D.A., Short, S.K., Andrews, J.T., Webber, P.J. 1981. Late Holocene pollen and present-day vegetation, Prudhoe Bay and Atigun River, Alaska. Arctic and Alpine Research 13. 153172.Google Scholar
Webb, T. III 1974. Corresponding patterns of pollen and vegetation in lower Michigan: A comparison of quantitative data. Ecology 55. 1728.Google Scholar
Wigley, T.M.L., Jones, P.D., Kelly, P.M. 1980. Scenario for a warm, high-CO2 world. Nature (London) 283. 1721.Google Scholar