Climatic Change

, Volume 14, Issue 1, pp 39–59 | Cite as

Reconstructed Northern Hemisphere annual temperature since 1671 based on high-latitude tree-ring data from North America

  • Gordon C. JacobyJr.
  • Rosanne D'Arrigo


Annual Northern Hemisphere surface temperature departures for the past 300 yr were reconstructed using eleven tree-ring chronologies from high-latitude, boreal sites in Canada and Alaska, spanning over 90 degrees of longitude. This geographic coverage is believed to be adequate for a useful representation of hemispheric-scale temperature trends, as high northern latitudes are particularly sensitive to climatic change. We also present a reconstruction of Arctic annual temperatures. The reconstructions show a partial amelioration of the Little Ice Age after the early 1700's, an abrupt, severe renewal of cold in the early 1800's and a prolonged wanning since approximately 1840. These trends are supported by other proxy data. Similarities and differences between our Northern Hemisphere reconstruction and other large-scale proxy temperature records depend on such factors as the data sources, methods, and degree of spatial representation. Analyses of additional temperature records, as they become available, are needed to determine the degree to which each series represents fluctuations for the entire hemisphere. There appear to be relationships between trends observed in our Northern Hemisphere reconstruction and certain climatic forcing functions, including solar fluctuations, volcanic activity and atmospheric CO2. In particular, our reconstruction supports the hypothesis that the global warming trend over the past century of increasing atmospheric CO2 has exceeded the recent level of natural variability of the climate system.


Temperature Record Proxy Data High Northern Latitude Hemisphere Surface Proxy Temperature 
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  1. Barnett, T. P.: 1978, ‘Estimating Variability of Surface Air Temperature in the Northern Hemisphere’, Mon Wea. Rev. 106, 1353–67.Google Scholar
  2. Borzenkova, I. I., Vinnikov, K. Ya., Spirina, L. P., and Stekhnovskii, D. I.: 1976, ‘Change in the Air Temperature of the Northern Hemisphere for the Period 1881–1975’, Met. I. Gidr. 7, 27–35.Google Scholar
  3. Bradley, R. S., Kelly, P. M., Jones, P. D., Goodess, C., Diaz, H., Barry, R. G., and Moses, T.: 1984, ‘Climate of the Northern Hemisphere 1851–1900 Compared to Contemporary Climate’, Second Annual Report to the U.S. Dept. of Energy (DEACO2-81–10739). University of Massachusetts, Amherst, Massachusetts.Google Scholar
  4. Bradley, R. S. and England, J.: 1978, ‘Recent Climatic Fluctuations of the Canadian High Arctic and their Significance for Glaciology’, Arctic and Alpine Res. 10, 715–31.Google Scholar
  5. Briffa, K. R., Wigley, T. M. L., Jones, P. D., Pilcher, J. R., and Hughes, M. K.: 1986, ‘The Reconstruction of Past Circulation Patterns over Europe using Tree-Ring Data’, Final Report Commission of the European Communities, Contract No. CL. 111.UK(H).Google Scholar
  6. Bryson, R. A.: 1976, ‘Perspective on Climatic Change’, Science 184, 753–60.Google Scholar
  7. Chang, J. H.: 1972, Atmospheric Circulation Systems and Climates, Oriental Publ. Co., Honolulu, 326 pp.Google Scholar
  8. Cook, E. R.: 1985, A Time-Series Analysis Approach to Tree-Ring Standardization, Ph.D. Thesis, University of Arizona, Tucson.Google Scholar
  9. Cook, E. R. and Jacoby, G. C.: 1977, ‘Tree-Ring Drought Relationships in the Hudson Valley, New York’, Science 198, 399–401.Google Scholar
  10. Cook, E. R. and Peters, K.: 1981, ‘The Smoothing Spline: a New Approach to Standardizing Forest Interior Ring-Width Series for Dendroclimatic Studies’, Tree Ring Bul. 41, 45–53.Google Scholar
  11. Cropper, J. P.: 1982, ‘Climate Reconstructions (1801 to 1938) inferred from Tree-Ring Width Chronologies of the North American Arctic’, Arctic and Alpine Res. 14, 223–41.Google Scholar
  12. Cropper, J. P. and Fritts, H. C.: 1981, ‘Tree-Ring Width Chronologies from the North American Arctic’, Arctic and Alpine Res. 13, 245–66.Google Scholar
  13. Dansgaard, W., Johnsen, S. J., Reeh, N., Gundestrup, N., Clausen, H. B., and Hammer, C. U.: 1975, ‘Climatic Changes, Norsemen and Modern Man’, Nature 255, 24–8.Google Scholar
  14. Eddy, J. A.: 1976, ‘The Maunder Minimum’, Science 192, 1189–1202.Google Scholar
  15. Ellsaesser, H. W.: 1986, ‘Comments on: Surface Temperature Changes Following the Six Major Volcanic Episodes between 1780 and 1980’, J. Clim. and Appl. Met. 25, 1184–5.Google Scholar
  16. Ellsaesser, H. W., MacCracken, M. C., Walton, J. J., and Grotch, S. L.: 1986, ‘Global Climatic Trends as Revealed by the Recorded Data’, Rev. Geophys. 24, 745–92.Google Scholar
  17. Fritts, H. C.: 1976, Tree Rings and Climate, Academic Press, New York.Google Scholar
  18. Fritts, H. C. and Lough, J. M.: 1985, ‘An Estimate of Average Annual Temperature Variations for North America, 1602–1961’, Clim. Change, 7, 203–24.Google Scholar
  19. Fritts, H. C., Mosimann, J. E., and Bottorff, C. P.: 1969, ‘A Revised Computer Program for Standardizing Tree-Ring Series’, Tree Ring Bul. 29, 15–20.Google Scholar
  20. Garfinkel, H. L. and Brubaker, L. B.: 1980, ‘Modern Climate-Tree Growth Relationships and Climatic Reconstruction in Sub-Arctic Alaska’ Nature 286, 872–74.Google Scholar
  21. Gilliland, R. L.: 1982, ‘Solar, Volcanic and CO2 Forcing of Recent Climatic Changes’, Climatic Change 4, 112–31.Google Scholar
  22. Goody, R.: 1980, ‘Polar Processes and World Climate’, Mon. Wea. Rev. 108, 1935–42.Google Scholar
  23. Goldstein, G. H.: 1981, ‘Ecophysiological and Demographic Studies of White Spruce (Picea glauca [Moench] Voss) at Treeline in the Central Brooks Range of Alaska’, Ph.D. Thesis, University of Washington, Seattle.Google Scholar
  24. Gordon, G. A. and LeDuc, S. K.: 1981, ‘Verification Statistics for Regression Models’ in Proceedings of Conference on Probability and Statistics in Atmospheric Science, November, 1981, Monterey, CA, 129-33.Google Scholar
  25. Gray, B. M.: 1974, ‘Early Japanese Winter Temperatures’, Weather 29, 103–7.Google Scholar
  26. Groveman, B. S. and Landsberg, H. E.: 1979, ‘Simulated Northern Hemisphere Temperature Departures 1579–1880’, Geophys. Res. Letters 6, 767–9.Google Scholar
  27. Hammer, C. U., Clausen, H. B., and Dansgaard, W.: 1981, ‘Past Volcanic and Climate Revealed by Greenland Ice Cores’, J. Volcanol. Geothermal Res. 11, 3–10.Google Scholar
  28. Hansen, J. E.: 1988, ‘The Greenhouse Effect: Impacts on Current Global Temperature and Regional Heat Waves’, Statement presented to: U.S. Senate, Committee on Energy and Natural Resources, June 23, 1988.Google Scholar
  29. Hansen, J., Fung, I., Lacis, A., Lebedeff, S., Rind, D., Ruedy, R., Russell, G., and Stone, P.: 1988, ‘Global Climate Changes as Forecast by the GISS 3-D Model’, J. Geophys. Res. 93, 9341–9364.Google Scholar
  30. Hansen, J. and Lebedeff, S.: 1987, ‘Global Trends of Measured Surface Air Temperature’, J. Geophys. Res. 92, 13345–372.Google Scholar
  31. Hansen, J. and Lebedeff, S.: 1988, ‘Global Surface Air Temperatures: Update through 1987’, Geophys. Res. Letters 15, 323–6.Google Scholar
  32. Hansen, J., Wang, W. C., and Lacis, A. A.: 1978, ‘Mount Agung Eruption Provides Test of a Global Climatic Perturbation’, Science 199, 1065–68.Google Scholar
  33. Hansen, J., Johnson, D., Lacis, A., Lebedeff, S., Lee, P., Rind, D., and Russell, G.: 1981, ‘Climatic Impact of Increasing Atmospheric Carbon Dioxide’, Science 213, 957–67.Google Scholar
  34. Hansen, J. and Takahashi, T.: 1984, Climate Processes and Climate Sensitivity, Geophysical Monograph 29, Maurice Ewing Vol. 5, American Geophysical Union.Google Scholar
  35. Hughes, M. K., Kelly, P. M., Pilcher, J. R., and LaMarche, V. C. Jr. (eds.): 1982, Climate from Tree-Rings, Cambridge University Press, Cambridge.Google Scholar
  36. Jacoby, G. C. Jr.: 1982, ‘The Arctic’, in Hughes, M. K., Kelly, P. M., Pilcher, J. R., and LaMarche, V. C. Jr., (eds.), Climate from Tree-Rings, Cambridge University Press, Cambridge.Google Scholar
  37. Jacoby, G. C. Jr. and Cook, E. R.: 1981, ‘Past Temperature Variations Inferred from a 400-yr Tree-Ring Chronology from Yukon Territory, Canada’, Arctic and Alpine Res. 13, 409–18.Google Scholar
  38. Jacoby, G. C. Jr. and Ulan, L. D.: 1982, ‘Reconstruction of Past Ice Conditions in a Hudson Bay Estuary using Tree-Rings’, Nature 298, 637–9.Google Scholar
  39. Jacoby, G. C. Jr., Cook, E. R., and Ulan, L. D.: 1985, ‘Reconstructed Summer Degree Days in Central Alaska and Northwestern Canada since 1524’, Quat. Res. 23, 18–26.Google Scholar
  40. Jones, P. D., Wigley, T. M. L., and Raper, S. C. B.: 1987, ‘The Rapidity of CO2-induced Climatic Change: Observations, Model Results and Paleoclimatic Implications’, in Berger, W. H. and Labeyrie, L. D., (eds.), Abrupt Climatic Change: Evidence and Implications, D. Reidel Publ. Co., Dordrecht, Holland.Google Scholar
  41. Jones, P. D., Raper, S. C. B., Bradley, R. S., Diaz, H. F., Kelly, P. M., and Wigley, T. M. L.: 1986a, ‘Northern Hemisphere Surface Air Temperature Variations, 1851–1984’, J. Clim. and Appl. Met. 25, 161–79.Google Scholar
  42. Jones, P. D., Wigley, T. M. L., and Wright, P. B.: 1986b, ‘Global Temperature Variations Between 1861 and 1984’, Nature 322, 430–434.Google Scholar
  43. Jones, P. D., Raper, S. C. B., and Wigley, T. M. L.: 1986c, ‘Southern Hemisphere Air Temperature Variations, 1851–1984’, J. Clim. and Appl. Met. 25, 1213–30.Google Scholar
  44. Jones, P. D. and Kelly, P. M.: 1983, ‘The Spatial and Temporal Characteristics of Northern Hemisphere Surface Air Temperature Variations’, J. of Climatology 3, 243–52.Google Scholar
  45. Jones, P. D., Wigley, T. M. L., and Kelly, P. M.: 1982, ‘Variations in Surface Air Temperature, I, Northern Hemisphere, 1881–1980’, Mon. Wea. Rev. 110, 59–70.Google Scholar
  46. Kelly, P. M., Jones, P. D., Sear, C. B., Cherry, B. S. G., and Tavakol, R. K.: 1982, ‘Variations in Surface Air Temperatures: Part 2, Arctic regions, 1881–1980’, Mon. Wea. Rev. 110, 71–83.Google Scholar
  47. Koerner, R. M.: 1977, ‘Devon Island Icecap: Core Stratigraphy and Paleoclimate’, Science 196, 15–18.Google Scholar
  48. Kozlowski, T. T.: 1971, Growth and Development of Trees, II. Cambial Growth, Root Growth, and Reproductive Growth, Academic Press, New York.Google Scholar
  49. Lachenbruch, A. H. and Marshall, B. V.: 1986, ‘Changing Climate: Geothermal Evidence from Permafrost in the Alaskan Arctic’, Science 234, 689–96.Google Scholar
  50. LaMarche, V. C., Jr.: 1974, ‘Paleoclimatic Inferences from Long Tree-Ring Records’, Science 183, 1043–8.Google Scholar
  51. LaMarche, V. C., Jr. and Stockton, C. W.: 1974, ‘Chronologies from Temperature-Sensitive Bristlecone Pines at Upper Treeline in Western United States’, Tree Ring Bul. 34, 21–45.Google Scholar
  52. LaMarche, V. C., Jr., Graybill, D. A., Fritts, H. C., and Rose, M. R.: 1984, ‘Increasing Atmospheric Carbon Dioxide: Tree-Ring Evidence for Growth Enhancement in Natural Vegetation’, Science 225, 1019–21.Google Scholar
  53. Lamb, H. H.: 1977, Climate: Past, Present and Future. II. Climate History and the Future, Methuen, London.Google Scholar
  54. Lamb, H. H.: 1982, Climate History and the Modern World, Methuen, London.Google Scholar
  55. Lamb, H. H. and Morth, H. T.: 1978, ‘Arctic Ice, Atmospheric Circulation and World Climate’, Geogr. J. 144 (Pt. 1), 1–22.Google Scholar
  56. Landsberg, H. E.: 1975, ‘Historic Weather Data and Early Meteorological Observations’, pp. 27–70. in Hecht, A. D. (ed.) Paleoclimatic Analysis and Modeling, J. Wiley and Sons, N.Y.Google Scholar
  57. Landsberg, H. E. and Albert, J. M.: 1974, ‘The Summer of 1816 and Volcanism’, Weatherwise 27, 63–6.Google Scholar
  58. Lorenz, E. N.: 1976, ‘Nondeterministic Theories of Climatic Change’, Quat. Res. 6, 495–506.Google Scholar
  59. Manabe, S. and Wetherald, R.: 1980, ‘On the Distribution of Climate Change Resulting from an Increase in the CO2 Content of the Atmosphere’, J. Atmos. Sci. 37, 99–118.Google Scholar
  60. Manley, G.: 1974, ‘Central England Temperatures: Monthly Means from 1659 to 1973’, Quat. J. Roy. Met. Soc. 100, 389–405.Google Scholar
  61. Meko, D. M.: 1981, Applications of Box-Jenkins Methods of Time Series Analysis to the Reconstruction of Drought from Tree-Rings, Ph.D. Thesis, Univ. of Arizona, Tucson.Google Scholar
  62. Mitchell, J. M. Jr.: 1975, ‘Note on the Solar Variability and Volcanic Activity as Potential Sources of Climatic Variability’, in The Physical Basis of Climate and Climate Modelling, Report of International Study Conference, 29 July–10 August 1974, Stockholm. GARP Publication Series No. 16, pp. 127–31.Google Scholar
  63. Neter, J. and Wasserman, F.: 1974, Applied Linear Statistical Models, Richard D. Irwin, Inc., Homewood, Ill. 842 pp.Google Scholar
  64. Oechel, W. C. and Riechers, G. W.: 1986, ‘Impacts of Increasing CO2 on Natural Vegetation, Particularly the Tundra’, in C. Rosenzweig and R. Dickinson, (eds.), Climate-Vegetation Interactions, Proceedings of a Workshop held at Goddard Space Flight Center, Greenbelt, MD. NASA Conference Publ. No. 2440, pp. 174–7.Google Scholar
  65. Paterson, W. S. B., Koerner, R. M., Fisher, D., Johnsen, S. J., Clausen, H. B., Dansgaard, W., Bucher, P., and Oeschger, H.: 1977, ‘An Oxygen-Isotope Climatic Record from the Devon Island Icecap, Arctic Canada’, Nature 266, 508–11.Google Scholar
  66. Robock, A.: 1979, ‘The “Little Ice Age”: Northern Hemisphere Average Observations and Model Calculations’, Science 206, 1402–4.Google Scholar
  67. Schonwiese, C. D.: 1984, ‘Northern Hemisphere Temperature Statistics and Forcing: 1579–1980 AD’, Arch. Met. Geoph. Biocl. Ser B35, 155–178.Google Scholar
  68. Schneider, S. H. and Mass, C.: 1975, ‘Volcanic Dust, Sunspots and Temperature Trends’, Science 190, 741–6.Google Scholar
  69. Self, S., Rampino, M. R., and Barbera, J. J.: 1981, ‘The Possible Effects of Large 19th and 20th Century Volcanic Eruptions on Zonal and Hemispheric Surface Temperatures’, J. Volc, and Geoth. Res. 11, 41–60.Google Scholar
  70. Stockton, C. W.: 1971, The Feasibility of Augmenting Hydrologic Records Using Tree-Ring Data, Ph.D. Thesis, University of Arizona, Tucson.Google Scholar
  71. Thompson, L. G., Mosley-Thompson, E., Dansgaard, W., and Grootes, P. M.: 1986, ‘The Little Ice Age as Recorded in the Stratigraphy of the Tropical Quelccaya Icecap’, Science 234, 361–4.Google Scholar
  72. Tranquillini, W.: 1979, Physiological Ecology of the Alpine Timberline, Springer-Verlag, New York.Google Scholar
  73. Van Loon, H. and Williams, J.: 1976, ‘The Connection Between Trends of Mean Temperature and Circulation at the Surface: Pt. 1 Winter. Pt. 2 Summer’, Mon. Wea. Rev. 104, 365–80; 1003–11.Google Scholar
  74. Washington, W. M. and Meehl, G. A.: 1984, ‘Seasonal Cycle Experiment on the Climate Sensitivity due to a Doubling of CO2 with an Atmospheric General Circulation Model Coupled to a Simple Mixed-Layer Ocean Model’, J. Geophys. Res. 89, 9475–503.Google Scholar
  75. Williams, L. D. and Wigley, T. M. L.: 1983, ‘A Comparison of Evidence for Late Holocene Summer Temperature Variations in the Northern Hemisphere’, Quat. Res. 20, 286–307.Google Scholar
  76. Willson, R. C., Hudson, H. S., Frohlich, C., and Brusa, R. W.: 1986, ‘Long-Term Downward Trend in Total Solar Irradiance’, Science 234, 1114–7.Google Scholar

Copyright information

© Kluwer Academic Publishers 1989

Authors and Affiliations

  • Gordon C. JacobyJr.
    • 1
  • Rosanne D'Arrigo
    • 1
  1. 1.Tree-Ring Laboratory, Lamont-Doherty Geological ObservatoryPalisadesU.S.A.

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