A noodle, hockey stick, and spaghetti plate: a perspective on high‐resolution paleoclimatology

Opinion

David Frank, Jan Esper, Eduardo Zorita, Rob Wilson

Published Online: May 14 2010

DOI: 10.1002/wcc.53

How to cite this article
Download citation
Contact the editor about this article
Authors: submit updates and notes
Comment on this article
Share

Full article on Wiley Online Library: HTML PDF

Can't access this content? Tell your librarian.

The high‐resolution reconstruction of hemispheric‐scale temperature variation over the past‐millennium benchmarks recent warming against more naturally driven climate episodes, such as the Little Ice Age and the Medieval Warm Period, thereby allowing assessment of the relative efficacies of natural and anthropogenic forcing factors. Icons of past temperature variability, as featured in the Intergovernmental Panel on Climate Change (IPCC) reports over nearly two decades, have changed from a schematic sketch in 1990, to a seemingly well‐solved story in 2001, to more explicit recognition of significant uncertainties in 2007. In this article, we detail the beginning of the movement to reconstruct large‐scale temperatures, highlight major steps forward, and present our views on what remains to be accomplished. Despite significant efforts and progress, the spatial representation of reconstructions is limited, and the interannual and centennial variation are poorly quantified. Research priorities to reduce reconstruction uncertainties and improve future projections, include (1) increasing the role of expert assessment in selecting and incorporating the highest quality proxy data in reconstructions (2) employing reconstruction ensemble methodology, and (3) further improvements of forcing series. We suggest that much of the sensitivity in the reconstructions, a topic that has dominated scientific debates, can be traced back to the input data. It is perhaps advisable to use fewer, but expert‐assessed proxy records to reduce errors in future reconstruction efforts. Copyright © 2010 John Wiley & Sons, Ltd.

Figure 1.

IPCC icons of temperatures over the past millennium. Sequence of the pre‐industrial to industrial temperatures as expressed in the 1990 (upper), 2001 (middle), and 2007 (lower) IPCC reports. Dashed lines represent mean temperatures at 1900 in the upper panel and for 1961–1990 in the middle and lower panels. The upper panel was graphically recreated, whereas the middle and lower panels are based upon data obtained at the NCDC webpage (). Curves illustrate the evolution of the ‘consensus views’ for large‐scale temperature change in the IPCC reports. See text for details.

[ Normal View 46K | Magnified View 87K ]

References

1 Knutti, R, Hegerl, GC. The equilibrium sensitivity of the Earth`s temperature to radiation changes. Nature Geosci, 2008, 1: 735–743.
2 Frank, DC, Esper, J, Raible, CC, Büntgen, U, Trouet, V, et al. Ensemble reconstruction constraints on the climate sensitivity of the global carbon cycle. Nature 2010, 463: 527–530.
3 Osborn, TJ, Briffa, KR. The real color of climate change? Science 2004, 306: 621–622.
4 Ammann, CM, Joos, F, Schimel, DS, Otto‐Bliesner, BL, Tomas, RA. Solar influence on climate during the past millennium: results from transient simulations with the NCAR Climate System Model. Proc Nat Acad Sci U S A 2007, 104: 3713–3718.
5 Esper, J, Wilson, RJS, Frank, DC, Moberg, A, Wanner, H, et al. Climate: past ranges and future changes. Quat Sci Rev 2005, 24: 2164–2166.
6 Cox, PM, Betts, RA, Jones, CD, Spall, SA, Totterdell, IJ. Acceleration of global warming due to carbon‐cycle feedbacks in a coupled climate model. Nature 2000, 408: 184–187.
7 Groveman, B, Landsberg, H. Simulated northern hemisphere temperature departures 1579–1880. Geophys Res Lett 1979, 6: 767–769.
8 Landsberg, H, Groveman, B, Hakkarinen, I. A simple method for approximating the annual temperature of the Northern Hemisphere. Geophys Res Lett 1978, 5: 505–506.
9 Jacoby, G, D`Arrigo, R. Reconstructed Northern Hemisphere annual temperature since 1671 based on high‐latitude tree‐ring data from North America. Clim Change 1989, 14: 39–59.
10 Fritts, H. Tree Rings and Climate. Caldwell: Blackburn Press; 1976; 567.
11 D`Arrigo, RD, Jacoby, GC. Secular trends in high northern latitude temperature reconstructions based on tree rings. Clim Change 1993, 25: 163–177.
12 Bradley, R, Jones, P. Little Ice Age summer temperature variations: their nature and relevance to recent global warming trends. The Holocene 1993, 3: 367–376.
13 Jones, P, Briffa, K, Barnett, T, Tett, S. High‐resolution palaeoclimatic records for the last millennium: interpretation, integration and comparison with General Circulation Model control‐run temperatures. The Holocene 1998, 8: 455–471.
14 Mann, ME, Bradley, RS, Hughes, MK. Global‐scale temperature patterns and climate forcing over the past six centuries. Nature 1998, 392: 779–787.
15 Pollack, HN, Huang, SP, Shen, PY. Climate change record in subsurface temperatures: a global perspective. Science 1998, 282: 279–281.
16 Mann, ME, Bradley, RS, Hughes, MK. Northern hemisphere temperatures during the past millennium: inferences, uncertainties, and limitations. Geophys Res Lett 1999, 26: 759–762.
17 Huang, SP, Pollack, HN, Shen, PY. Temperature trends over the past five centuries reconstructed from borehole temperatures. Nature 2000, 403: 756–758.
18 Briffa, K. Annual climate variability in the Holocene: interpreting the message of ancient trees. Quat Sci Rev 2000, 19: 87–105.
19 Crowley, T, Lowery, T. How warm was the medieval warm period? Ambio 2000, 29: 51–54.
20 Briffa, K, Osborn, T, Schweingruber, F, Harris, I, Jones, P, et al. Low‐frequency temperature variations from a northern tree ring density network. J Geophys Res: Atmospheres 2001, 106: 2929–2941.
21 Briffa, K, Osborn, T, Schweingruber, F, Jones, P, Shiyatov, S, et al. Tree‐ring width and density data around the Northern Hemisphere: part 2, spatio‐temporal variability and associated climate patterns. The Holocene 2002, 12: 759–789.
22 Esper, J, Cook, E, Schweingruber, F. Low‐frequency signals in long tree‐ring chronologies for reconstructing past temperature variability. Science 2002, 295: 2250–2253.
23 Mann, ME, Jones, PD. Global surface temperatures over the past two millennia. Geophys Res Lett 2003, 30: 1820. DOI:10.1029/2003GL017814.
24 Huang, S. Merging information from different resources for new insights into climate change in the past and future. Geophys Res Lett 2004, 31: L13205. DOI: 10.1029/2004gl019781.
25 Oerlemans, J. Extracting a climate signal from 169 glacier records. Science 2005, 308: 675–677.
26 Moberg, A, Sonechkin, D, Holmgren, K, Datsenko, N, Karlén, W. Highly variable Northern Hemisphere temperatures reconstructed from low‐and high‐resolution proxy data. Nature 2005, 433: 613–617.
27 Rutherford, S, Mann, ME, Osborn, TJ, Bradley, RS, Briffa, KR, et al. Proxy‐based Northern Hemisphere surface temperature reconstructions: sensitivity to method, predictor network, target season, and target domain. J Clim 2005, 18: 2308–2329.
28 D`Arrigo, R, Wilson, R, Jacoby, G. On the long‐term context for late twentieth century warming. J Geophys Res 2006, 111: D03103.
29 Smith, CL, Baker, A, Fairchild, IJ, Frisia, S, Borsato, A. Reconstructing hemispheric‐scale climates from multiple stalagmite records. Int J Clim 2006, 26: 1417–1424.
30 Ammann, CM, Wahl, ER. The importance of the geophysical context in statistical evaluations of climate reconstruction procedures. Clim Change 2007, 85: 71–88.
31 Hegerl, GC, Crowley, TJ, Allen, M, Hyde, WT, Pollack, HN, et al. Detection of human influence on a new, validated 1500‐year temperature reconstruction. J Clim 2007, 20: 650–666.
32 Juckes, MN, Allen, MR, Briffa, KR, Esper, J, Hegerl, GC, et al. Millennial temperature reconstruction intercomparison and evaluation. Clim Past 2007, 3: 591–609.
33 Frank, D, Esper, J, Cook, ER. Adjustment for proxy number and coherence in a large‐scale temperature reconstruction Geophys. Res Lett 2007, 34: L16709. DOI:10.1029/2007gl030571.
34 Wilson, R, D`Arrigo, R, Buckley, B, Büntgen, U, Esper, J, et al. A matter of divergence: tracking recent warming at hemispheric scales using tree ring data. J Geophys Res: Atmospheres 2007, 112: D17103. DOI:10.1029/2006JD008318.
35 Loehle, C. A 2000‐Year global temperature reconstruction based on non‐treering proxies. Energy Environ 2007, 18: 1049–1058.
36 Mann, ME, Zhang, ZH, Hughes, MK, Bradley, RS, Miller, SK, et al. Proxy‐based reconstructions of hemispheric and global surface temperature variations over the past two millennia. Proc Natl Acad Sci U S A 2008, 105: 13252–13257.
37 Houghton, J, Jenkins, G, Ephraums, J Climate change: The IPCC Scientific Assessment. World Meteorological Organization, United Nations Environmental Programme. Cambridge, England: Cambridge University Press; 1990; 406.
38 Houghton, J, Ding, Y, Griggs, D, Noguer, M, Van der Linden, P, et al. Climate Change 2001: The Scientific Basis. Cambridge: Cambridge University Press; 2001, 881.
39 IPCC Climate Change. The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press; 2007.
40 Jones, PD, Briffa, KR, Osborn, TJ, Lough, JM, van Ommen, TD, et al. High‐resolution palaeoclimatology of the last millennium: a review of current status and future prospects. The Holocene 2009, 19: 3–49.
41 Lamb, H. The early medieval warm epoch and its sequel. Palaeogeogr Palaeoclimatol Palaeoecol 1965, 1: 13–37.
42 Regalado, A, Climate Debate, The ‘Hockey Stick’Leads to a Face‐Off. The Wall Street Journal, February 14. 2005, A1.
43 North, G, Biondi, F, Bloomfield, P, Christy, J, Cuffey, K, et al. Surface Temperature Reconstructions for the Last 2,000 Years. Washington, D.C.: The National Academies Press; 2006.
44 Esper, J, Cook, E, Krusic, P, Peters, K, Schweingruber, F. Tests of the RCS method for preserving low‐frequency variability in long tree‐ring chronologies. Tree‐Ring Res 2003, 59: 81–98.
45 Ojala, AEK, Alenius, T. 10,000 years of interannual sedimentation recorded in the Lake Nautajärvi (Finland) clastic‐organic varves. Palaeogeogr Palaeoclimatol Palaeoecol 2005, 219: 285–302.
46 Mann, M, Rutherford, S, Wahl, E, Ammann, C. Testing the fidelity of methods used in proxy‐based reconstructions of past climate. J Clim 2005, 18: 4097–4107.
47 Moberg, A, Mohammad, R, Mauritsen, T Analysis of the Moberg et al. (2005) hemispheric temperature reconstruction. Clim Dyn 2008, 31: 957–971.
48 Osborn, T, Briffa, K. Revisiting timescale‐dependent reconstruction of climate from tree‐ring chronologies. Dendrochronologia 2000, 18: 9–25.
49 von Storch, H, Zorita, E, Gonzàlez‐Rouco, F. Assessment of three temperature reconstruction methods in the virtual reality of a climate simulation. Int J Earth Sci 2009, 98: 67–82.
50 Christiansen, B, Schmith, T, Thejll, P. A surrogate ensemble study of climate reconstruction methods: stochasticity and robustness. J Clim 2009, 22: 951–976.
51 Lee, T, Zwiers, F, Tsao, M. Evaluation of proxy‐based millennial reconstruction methods. Clim Dyn 2008, 31: 263–281.
52 Thejll, P, Schmith, T. Limitations on regression analysis due to serially correlated residuals: application to climate reconstruction from proxies. J Geophys Res: Atmospheres 2005, 110: D18103. DOI:10.1029/2005jd005895.
53 Esper, J, Frank, DC, Wilson, RJS, Briffa, KR. Effect of scaling and regression on reconstructed temperature amplitude for the past millennium Geophys. Res Lett 2005: 32: L07711. DOI:10.1029/2004GL021236.
54 Frank, D, Büntgen, U, Bohm, R, Maugeri, M, Esper, J. Warmer early instrumental measurements versus colder reconstructed temperatures: shooting at a moving target. Quat Sci Rev 2007, 26: 3298–3310.
55 Cook, ER, Pederson, N. %22Uncertainty, emergence, and statistics in dendrochronology%22. In: Hughes, MK, Diaz, H, Swetnam, TW, eds. Dendroclimatology: Progress and Prospects. New York: Springer; 2009.
56 Wilson, R, Tudhope, A, Brohan, P, Briffa, K, Osborn, T, et al. Two‐hundred‐fifty years of reconstructed and modeled tropical temperatures. J Geophys Res: Oceans 2006, 111: 13.
57 Büntgen, U, Frank, D, Grudd, H, Esper, J. Long‐term summer temperature variations in the Pyrenees. Clim Dyn 2008, 31: 615–631.
58 Frank, D, Esper, J. Temperature reconstructions and comparisons with instrumental data from a tree‐ring network for the European Alps. Int J Climatol 2005, 25: 1437–1454.
59 Böhm, R, Jones, PD, Hiebl, J, Frank, D, Brunetti, M, et al. The early instrumental warm‐bias: a solution for long central European temperature series 1760–2007. Clim Change DOI:10.1007/s10584‐009‐9649‐4.
60 Thompson, D, Kennedy, J, Wallace, J, Jones, P. A large discontinuity in the mid‐twentieth century in observed global‐mean surface temperature. Nature 2008, 453: 646–649.
61 Hughes, M, Diaz, H. Was there a “Medieval Warm Period”, and if so, where and when? Clim Change 1994, 26: 109–142.
62 Bradley, R, Hughes, M, Diaz, H. Climate change: climate in medieval time. Science 2003, 302: 404.
63 Esper, J, Frank, D. The IPCC on a heterogeneous Medieval Warm Period. Clim Change 2009, 94: 267–273.
64 Trouet, V, Esper, J, Graham, NE, Baker, A, Scourse, JD, et al. Persistent positive north Atlantic oscillation mode dominated the medieval climate anomaly. Science 2009, 324: 78–80.
65 Büntgen, U, Frank, DC, Nievergelt, D, Esper, J. Summer temperature variations in the European Alps, AD 755–2004. J Clim 2006, 19: 5606–5623.
66 Cook, ER, Woodhouse, CA, Eakin, CM, Meko, DM, Stahle, DW. Long‐term aridity changes in the western US Science. 2004, 306: 1015–1018.
67 Graham, NE, Hughes, MK, Ammann, CM, Cobb, KM, Hoerling, MP, et al.Tropical Pacific –mid‐latitude teleconnections in medieval times. Clim Change 2007, 83: 241–285.
68 Seager, R, Graham, N, Herweijer, C, Gordon, AL, Kushnir, Y, et al. Blueprints for medieval hydroclimate. Quat Sci Rev 2007, 26: 2322–2336.
69 Mann, ME, Cane, MA, Zebiak, SE, Clement, A. Volcanic and solar forcing of the tropical Pacific over the past 1000 years. J Clim 2005, 18: 447–456.
70 Emile‐Geay, J, Cane, M, Seager, R, Kaplan, A, Almasi, P. El Nino as a mediator of the solar influence on climate. Paleoceanography 2007, 22: 16.
71 Von Storch, H, Zorita, E, Jones, J, Dimitriev, Y, Gonzalez‐Rouco, F, et al. Reconstructing past climate from noisy data. Science 2004, 306: 679–682.
72 Babbage, C. Passages from the Life of a Philosopher: London: Longman, Roberts, %26 Green, 1864.
73 van der Schrier, G, Osborn, TJ, Briffa, KR, Cook, ER. Exploring an ensemble approach to estimating skill in multiproxy palaeoclimate reconstructions. The Holocene 2007, 17: 119–129.
74 Esper, J, Frank, D, Buntgen, U, Verstege, A, Luterbacher, J. Long‐term drought severity variations in Morocco. Geophys Res Lett 2007, 34: L17702. DOI:10.1029/2007gl030844.
75 Klein, JR, Roodman, A. Blind analysis in nuclear and particle physics. Ann Rev Nuclear Particle Sci 2005, 55: 141–163.
76 Gao, CC, Robock, A, Ammann, C. Volcanic forcing of climate over the past 1500 years: an improved ice core‐based index for climate models. J Geophys Res: Oceans 2008; 113: D23111. DOI:10.1029/2008jd010239.
77 Steinhilber, F, Beer, J, Frohlich, C. Total solar irradiance during the Holocene. Geophys Res Lett 2009, 36: 5.
78 Pongratz, J, Reick, C, Raddatz, T, Claussen, M. A reconstruction of global agricultural areas and land cover for the last millennium. Global Biogeochem Cycles 2008, 22. DOI: 10.1029/2007 gb003153.
79 Wanner, H, Beer, J, Butikofer, J, Crowley, TJ, Cubasch, U, et al. Mid‐ to Late Holocene climate change: an overview. Quat Sci Rev 2008, 27: 1791–1828.
80 Wagner, S, Zorita, E. The influence of volcanic, solar and the Dalton Minimum (1790–1830): CO₂ forcing on the temperatures in a model study. Clim Dyn 2005, 25: 205–218.
81 Pitman, AJ, de Noblet‐Ducoudre, N, Cruz, FT, Davin, EL, Bonan, GB, et al. Uncertainties in climate responses to past land cover change: first results from the LUCID intercomparison study. Geophys Res Lett 2009, 36: L14814. DOI: 10.1029/2009gl039076.
82 Jungclaus, J, et al. Ensemble simulations of the Last Millennium using an Earth System Model including an interactive carbon cycle. Geophysical Res 2009, 11:EGU2009–EGU4043.
83 Zorita, E, Gonzalez‐Rouco, F, Legutke, S. Testing the Mann et al. (1998) approach to paleoclimate reconstructions in the context of a 1000‐yr control simulation with the ECHO‐G coupled climate model. J Clim 2003, 16: 1378–1390.
84 Crowley, TJ. Causes of climate change over the past 1000 years. Science 2000, 289: 270–277.

blog comments powered by Disqus

Society Partners

	Royal Geographical Society (with IBG)
	Royal Meteorological Society

Access to this WIREs title is by subscription only.

Recommend to Your
Librarian Now!

Article Title	A noodle, hockey stick, and spaghetti plate: a perspective on high‐resolution paleoclimatology
* Name
* E-mail
* Note

A noodle, hockey stick, and spaghetti plate: a perspective on high‐resolution paleoclimatology

Society Partners

Access to this WIREs title is by subscription only.

The latest WIREs articles in your inbox

Twitter: WIREs_Climate Follow us on Twitter

A noodle, hockey stick, and spaghetti plate: a perspective on high‐resolution paleoclimatology

Related Articles

Browse by Topic

Society Partners

Access to this WIREs title is by subscription only.

The latest WIREs articles in your inbox

Twitter: WIREs_Climate Follow us on Twitter