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Inter-hemispheric temperature variability over the past millennium

Abstract

The Earth’s climate system is driven by a complex interplay of internal chaotic dynamics and natural and anthropogenic external forcing. Recent instrumental data have shown a remarkable degree of asynchronicity between Northern Hemisphere and Southern Hemisphere temperature fluctuations, thereby questioning the relative importance of internal versus external drivers of past as well as future climate variability1,2,3. However, large-scale temperature reconstructions for the past millennium have focused on the Northern Hemisphere4,5, limiting empirical assessments of inter-hemispheric variability on multi-decadal to centennial timescales. Here, we introduce a new millennial ensemble reconstruction of annually resolved temperature variations for the Southern Hemisphere based on an unprecedented network of terrestrial and oceanic palaeoclimate proxy records. In conjunction with an independent Northern Hemisphere temperature reconstruction ensemble5, this record reveals an extended cold period (1594–1677) in both hemispheres but no globally coherent warm phase during the pre-industrial (1000–1850) era. The current (post-1974) warm phase is the only period of the past millennium where both hemispheres are likely to have experienced contemporaneous warm extremes. Our analysis of inter-hemispheric temperature variability in an ensemble of climate model simulations for the past millennium suggests that models tend to overemphasize Northern Hemisphere–Southern Hemisphere synchronicity by underestimating the role of internal ocean–atmosphere dynamics, particularly in the ocean-dominated Southern Hemisphere. Our results imply that climate system predictability on decadal to century timescales may be lower than expected based on assessments of external climate forcing and Northern Hemisphere temperature variations5,6 alone.

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Figure 1: Proxy data and calibration performance.
Figure 2: Temperature variability over the past millennium.
Figure 3: Extreme periods.
Figure 4: Inter-hemispheric temperature difference.

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Acknowledgements

This work has been possible thanks to the collaboration of many members of the Australasian, South American, African and Antarctic working groups of the PAGES Regional 2K initiative. Researchers from these working groups are warmly thanked for providing metadata inventories and access to data. S. J. Phipps is acknowledged for support with model data. We acknowledge funding from the Swiss National Science Foundation and funding from the Australian Research Council (Projects LP0990151 and DE130100668) and the Australian Department of Climate Change and Energy Efficiency.

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Contributions

R.N. performed data analyses and developed the figures and tables. R.N., D.F. and J.G. led the writing of the paper. R.N., J.G., D.J.K., H.W. and D.F. designed the study. M.C., J.E., B.K.L, A.D.M., I.M., E.J.S., T.V., R.V., T.v.O. and J.Z. assisted with proxy data and F.G. and C.C.R. with climate model data. All authors discussed the results and commented jointly on the manuscript.

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Correspondence to Raphael Neukom.

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The authors declare no competing financial interests.

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Neukom, R., Gergis, J., Karoly, D. et al. Inter-hemispheric temperature variability over the past millennium. Nature Clim Change 4, 362–367 (2014). https://doi.org/10.1038/nclimate2174

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