Abstract
We present a significant update to a millennial summer temperature reconstruction (1073–1983) that was originally published in 1997. Utilising new tree-ring data (predominantly Picea engelmannii), the reconstruction is not only better replicated, but has been extended (950–1994) and is now more regionally representative. Calibration and verification statistics were improved, with the new model explaining 53% of May–August maximum temperature variation compared to the original (39% of April–August mean temperatures). The maximum latewood density data, which are weighted more strongly in the regression model than ringwidth, were processed using regional curve standardisation to capture potential centennial to millennial scale variability. The reconstruction shows warm intervals, comparable to twentieth century values, for the first half of the eleventh century, the late 1300s and early 1400s. The bulk of the record, however, is below the 1901–1980 normals, with prolonged cool periods from 1200 to 1350 and from 1450 to the late 19th century. The most extreme cool period is observed to be in the 1690s. These reconstructed cool periods compare well with known regional records of glacier advances between 1150 and the 1300s, possibly in the early 1500s, early 1700s and 1800s. Evidence is also presented of the influence of solar activity and volcanic events on summer temperature in the Canadian Rockies over the last 1,000 years. Although this reconstruction is regional in scope, it compares well at multi-decadal to centennial scales with Northern Hemisphere temperature proxies and at millennial scales with reconstructions that were also processed to capture longer timescale variability. This coherence suggests that this series is globally important for the assessment of natural temperature variability over the last 1,000 years.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Bard E, Raisbeck G, Yiou F, Jouzel J (2000) Solar irradiance during the last 1,200 years based on cosmogenic nuclides. Tellus B 52(3):985–992
Beer J, Mende W, Stellmacherb R (2000) The role of the Sun in climate forcing. Q Sci Rev 19:403–415
Bond G, Kromer B, Beer J, Muscheler R, Evans MN, Showers W, Hoffmann S, Lotti-Bond R, Hajdas I, Bonani G (2001) Persistent solar influence on North Atlantic climate during the Holocene. Science 294:2130–2136
Briffa KR (1995) Interpreting high-resolution proxy climate data: the example of dendroclimatology. In: von Storch H and Navarra A (eds) Analysis of climate variability, applications of statistical techniques. Springer, Berlin Heidelberg New York, pp 77–94
Briffa KR (2000) Annual climate variability in the Holocene: interpreting the message from ancient trees. Q Sci Rev 19:87–105
Briffa KR, Melvin T (2004) A closer look at regional chronology standardisation of tree-ring records: justification of the need, a warning of some pitfalls, and suggested improvements in its application. In: Tree rings and climate: sharpening the focus [oral presentation]. Tucson, Arizona, 6–9 April 2004
Briffa K, Jones P, Bartholin T, Eckstein D, Schweingruber F, Karlen W, Zetterberg P, Eronen M (1992) Fennoscandian summers from AD 500: temperature changes on short and long time scales. Clim Dyn 7:111–119
Briffa K, Jones P, Schweingruber F, Karlen W, Shiyatov G (1996) Tree ring variables as proxy climate indicators: problems with low-frequency signals. In: Jones P, Bradley RS, Jouzel J (eds) Climatic variations and forcing mechanisms of the last 2,000 years. Springer, Berlin Heidelberg New York, pp 9–41
Briffa K, Jones P, Schweingruber F, Osborn T (1998) Influence of volcanic eruptions on Northern Hemisphere summer temperature over the past 600 years. Nature 393:450–454
Colenutt ME (2000) Climate reconstruction in the southern Canadian Rockies using tree-ring data from Alpine Larch. PhD Thesis, University of Western Ontario
Colenutt ME, Luckman BH (1996) Dendroclimatic characteristics of Alpine Larch (Larix lyallii, Parl) at treeline sites in western Canada. In: Dean JS, Meko DM, Swetnam TW (eds) Tree Rings, environment and humanity. Tucson; Radiocarbon 38:143–154
Cook ER, Peters K (1997) Calculating unbiased tree-ring indices for the study of climate and environmental change. Holocene 7(3):361–370
Cook ER, Briffa KR, Jones PD (1994) Spatial regression methods in dendroclimatology: a review and comparison of two techniques. Int J Climatol 14:379–402
Cook E, Briffa K, Meko D, Graybill D, Funkhouser G (1995) The ’segment length curse’ in long tree-ring chronology development for palaeoclimatic studies. Holocene 5:229–37
Crowley TJ (2000) Causes of climate change over the last 1,000 years. Science 289:270–277
Davi NK, Jacoby GC, Wiles GC (2003) Boreal temperature variability inferred from maximum latewood density and tree-ring width data, Wrangell Mountain region, Alaska. Q Res 60(3):252–262
Diaz HF (1996) Temperature changes on long time and large spatial scales: inferences from instrumental and proxy records. In: Jones PD, Bradley RS, Jouzel J (eds) Climate variations and forcing mechanisms of the last 2,000 years. Springer, Berlin Heidelberg New York, pp 585–601
Efron B (1987) Better bootstrap confidence intervals. J Am Stat Assoc 82:171–185
Esper J, Cook E, Schweingruber F (2002) Low-frequency signals in long tree-ring chronologies and the reconstruction of past temperature variability. Science 295:2250–2253
Esper J, Cook ER, Krusic PJ, Peters K, Schweingruber FH (2003) Tests of the RCS method for reserving low-frequency variability in long tree-ring chronologies. Tree-Ring Res 59:81–98
Esper J, Frank D, Wilson RJS (2004) Climate reconstructions: low-frequency ambition and high-frequency ratification. EOS 85(12):113, 120
Hughes MK, Diaz HF (1994) Was there a “Medieval Warm Period” and if so, where and when? Clim Change 26:109–142
Kavanagh TA (2000) A reconstruction of treeline dynamics in Sunwapta Pass, Alberta. PhD Thesis, University of Western Ontario
Kirchner I, Stenchikov G, Graf HF, Robock A, Antuna J (1999) Climate model simulation of winter warming and summer cooling following the 1991 Mount Pinatubo volcanic eruption. J Geophys Res 104:19039–19055
Lamb HH (1965) The early medieval warm epoch and its sequel. Palaeogeogr Palaeoclimatol Palaeoecol 1:13–37
Luckman BH (1993) Glacier fluctuations and tree-ring records for the last millennium in the Canadian Rockies. Q Sci Rev 16:441–450
Luckman BH (1994) Climate conditions between ca 900–1300 AD in the southern Canadian Rockies. Clim Change 26:171–182
Luckman BH (1995) Calendar-dated, early Little Ice Age glacier advance at Robson Glacier, British Columbia, Canada. Holocene 5:149–159
Luckman BH (1996) Dendroglaciology at Peyto Glacier, Alberta. In: Dean JS, Meko DS, Swetnam TW (eds) Tree rings, environment and humanity. Tucson; Radiocarbon 38:679–688
Luckman BH (1997) Developing a proxy climate record for the last 300 years in the Canadian Rockies—some problems and opportunities. Clim Change 36:455–476
Luckman BH (2000) The Little Ice Age in the Canadian Rockies. Geomorphology 32:357–384
Luckman BH (2004) Neoglaciation. In: Goudie A (ed) Dictionary of geomorphology. International Association of Geomorphology, Routledge, pp 711–713
Luckman BH, Kavanagh TA (2000) Impact of climate fluctuations on mountain environments in the Canadian Rockies. Ambio 29(7):371–380
Luckman BH, Seed ED (1995) Fire–climate relationships and trends in the mountain national parks. Final report: Contract C2242-4-2185, Parks Canada, Ottawa, p 204
Luckman BH, Villalba R (2001) Assessing synchroneity of glacier fluctuations in the western cordillera of the Americas during the last millennium. In: Markgraf V (ed) Interhemispheric climate linkages. Academic, San Diego, pp 119–140
Luckman BH, Briffa KR, Jones PD, Schweingruber FH (1997) Tree-ring based reconstruction of summer temperatures at the Columbia Icefield, Alberta, Canada, AD 1073–1983. Holocene 7:375–389
Mann M, Bradley R, Hughes M (1999) Northern Hemisphere temperatures during the past millennium: inferences, uncertainties and limitations. Geophys Res Lett 26:759–762
Melvin T (2004) Historical growth rates and changing climatic sensitivity of Boreal Conifers. Dissertation, School of Environmental Sciences, University of East Anglia
Milewska E, Hogg WD (2001) Spatial representativeness of a long-term climate network in Canada. Atmos Ocean 39(2):145–161
Mitchell V (1967) An investigation of certain aspects of tree growth rates in relation to climate in the central Canadian boreal forest. Technical Report. No. 33, Department of Meteorology, University of Wisconsin, Wisconsin, p 62
Newhall CG, Self S (1982) The volcanic explosivity index (VEI): an estimate of explosive magnitude for historical volcanism. J Geophys Res 87:1231–1238
Oppenheimer C (2003) Ice core and palaeoclimatic evidence for the timing and nature of the great mid-13th century volcanic eruption. Int J Climatol 23:417–426
Osborn TJ, Briffa KB, Jones PD (1997) Adjusting variance for sample size in tree-ring chronologies and other regional mean timeseries. Dendrochronologia 15:89–99
Osborn GD, Robinson BJ, Luckman BH (2001) Holocene and latest Pleistocene fluctuations of Stutfield Glacier, Canadian Rockies. Can J Earth Sci 38:1141–1155
Robertson A, Overpeck J, Rind D, Mosley-Thompson E, Zielinski G, Lean J, Penner J, Tegen I, Healy R (2001) Hypothesized climate forcing time series for the last 500 years. J Geophys Res 106(D14):14783–14803
Schweingruber FH (1988) A new dendroclimatic network for western North America. Dendrochronologia 6:171–180
Shindell DT, Schmidt GA, Mann ME, Rind D, Waple A (2001) Solar forcing of regional climate change during the Maunder Minimum. Science 294:2149–2152
Stuiver M (1961) Variations in radiocarbon concentration and Sunspot activity. J Geophys Res 66:273–276
Wigley T, Briffa K, Jones P (1984) On the average value of correlated time series, with applications in dendroclimatology and hydrometeorology. J Clim Appl Met 23:201–213
Wiles GC, D’Arrigo RD, Villalba R, Calkin PE, Barclay DJ (2004) Century-scale solar variability and Alaskan temperature change over the past millennium. Geophys Res Lett 31:L15203. DOI 10.1029/2004GL020050
Wilson RJS, Luckman BH (2002) Tree-ring reconstruction of maximum and minimum temperatures and the diurnal temperature range in British Columbia, Canada. Dendrochronologia 20:257–268
Wilson RJS, Luckman BH (2003) Dendroclimatic reconstruction of maximum summer temperatures from upper treeline sites in interior British Columbia, Canada. Holocene 13:851–861
Youngblut DK (2003) The dendroclimatic potential of whitebark pine in the western Canadian Cordillera. M.Sc Thesis, University of Western Ontario, p 182
Zhang X, Vincent LA, Hogg WD, Niitsoo A (2000) Temperature and precipitation trends in Canada during the 20th century. Atmos Ocean 38(3):395–429
Zielinski GA (2000) Use of paleo-records in determining variability within the volcanism-climate system. Q Sci Rev 19:417–438
Acknowledgements
Funding support from the Natural Sciences and Engineering Research Council of Canada, the Canadian Foundation for Climate and Atmospheric Sciences, Parks Canada and the Inter-American Institute for Global Change Research is gratefully acknowledged. We thank Fritz Schweingruber, Ernest Schär and Theodor Forster at WSL for processing the densitometric data; Trudy Kavanagh for permission to use her Hilda data-set; Yves Bégin (Laval University) for wood identification; Carla Aruani for calculating pith offset data and many individuals who, over the years, have assisted in the collection of samples in the Canadian Rockies; and Dave Frank for proof-reading the final manuscript.
Author information
Authors and Affiliations
Corresponding author
Additional information
Authors are listed alphabetically
Appendix
Appendix
1.1 Developing the RCS chronology for the MXD data
Regional curve standardisation (RCS) attempts to capture low-frequency information that is greater than the mean length of the tree-ring series used to build a chronology (Esper et al. 2003). In its most basic form, RCS aligns all available tree-ring series by cambial age to develop a mean series of ‘average behaviour’ that is typical for the species and region. Deviations of individual series from this regional curve are interpreted as ecological or climatological signals that result in higher or lower growth rates. By averaging the detrended series, the common ‘climate’ signal is accentuated, while the ‘ecological’ noise is minimised. However, great care needs to be taken when utilising the RCS method because (1) tree-ring data-sets may represent different populations (i.e. differing growth rates or growth trend types) that cannot be modelled by a single mean regional curve without introducing significant bias into the final chronology (Esper et al. 2003) and (2) an unquantifiable systematic bias may also be introduced into a RCS chronology when the mean biological age of all samples varies over time which results in inflation or depression of index values at either end of the sample time-series (Briffa and Melvin 2004; Melvin 2004).
To address the potential occurrence of differing ‘populations’ within the MXD data, the MXD series were divided into three groups, to allow better assessment of potential bias from the RCS method (Table 4). These groups are (1) all series from living trees at the Peyto and the Icefield sites; (2) snag data from the Icefield site and (3) snag data from the Peyto and Robson sites. For each sample, pith offset data were estimated (Aruani and J. Esper, 2004, personal communication) to reduce potential bias in generating the cambial age-aligned curves. The pith offsets for the living samples are generally higher than those for the snag material (mainly discs), as many cores did not reach the pith. Separate RCS curves were developed for each group (Fig. 7a). The Peyto–Robson snags were treated as a separate group because their mean MXD values are generally higher than for the other two data-sets. Using a single, regional curve would inflate the final indexed values for the Peyto–Robson data, possibly introducing bias in the earliest part of the reconstruction. The 95% confidence envelopes (Fig. 7b) for each age-aligned curve show that the mean functions are generally robust over their entire length.
RCS chronology development. a Mean regional cambial age-aligned curves for the three-sub-group data-sets; b Mean regional age-aligned curves with two sigma error bars; c Comparison of the sub-group RCS chronologies; d Mean cambial age of all MXD samples for each year
The age-aligned curves (Fig. 7a) were smoothed with a cubic spline of 10% their length and used to standardise each maximum density series in their respective groups. This is the same method used by Esper et al. (2003). The final group RCS chronologies are compared in Fig. 7c. The correlation between the living tree and snag series from sites near the Columbia Icefield is reasonable (r=0.61, 1608–1897) but that between Icefields and the Peyto–Robson snags is more noisy (r=0.41, 1072–1312), probably reflecting the low replication of both series in this overlap period (Fig. 3a). The reasonably good fit between the three group chronologies (Fig. 7c) implies that the low frequency trends captured using RCS are real and not an artefact of the detrending procedure. Importantly, the good comparison between the Icefield Snag and Living RCS chronologies around 1700 (Fig. 7c) indicates that the low index values over this period (see also Fig. 3a) portray a relatively robust non-biased signal and are therefore likely not artificially depressed due to under-fitting of the age-aligned curves (Briffa and Melvin 2004; Melvin 2004) because of the low mean cambial age of the samples at this time (Fig. 7d).
The final MXD RCS chronology was developed by averaging the individual detrended series from all groups (Fig. 3a). An alternate MXD RCS chronology, generated without pith offset information was very similar to that presented here (r=0.986, 869–1994). This observation supports comments and analysis presented by Esper et al. (2003) that the lack of pith-offset information does not pose a serious bias when using RCS so long as sample replication is reasonably high.
Rights and permissions
About this article
Cite this article
Luckman, B.H., Wilson, R.J.S. Summer temperatures in the Canadian Rockies during the last millennium: a revised record. Clim Dyn 24, 131–144 (2005). https://doi.org/10.1007/s00382-004-0511-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00382-004-0511-0