![Figure 3. (a) Average ground surface temperature history (GSTH) for the full Urals borehole ensemble comprising 66 sites. Shaded area represents ±1 standard error of the mean. Superimposed is the time series (5-year moving average) of the surface air temperature (SAT) [Jones et al., 1999a]. Because the SAT is referenced to the mean over 19611990, and the geothermal reconstruction is referenced to the year 2000, we have shifted the SAT series along the temperature axis to enable an easier comparison of their respective trends. (b) Average GSTHs for the Central Urals subset (31 sites) and the South Urals subset (35 sites), shown within the standard error envelope of the full Urals data set shown above in Figure 3a.](https://www.researchgate.net/profile/Shaopeng-Huang-2/publication/12621407/figure/fig5/AS:667035348529158@1536045028069/a-Average-ground-surface-temperature-history-GSTH-for-the-full-Urals-borehole_Q320.jpg)
March 2000
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Nature
For an accurate assessment of the relative roles of natural variability and anthropogenic influence in the Earth's climate, reconstructions of past temperatures from the pre-industrial as well as the industrial period are essential. But instrumental records are typically available for no more than the past 150 years. Therefore reconstructions of pre-industrial climate rely principally on traditional climate proxy records, each with particular strengths and limitations in representing climatic variability. Subsurface temperatures comprise an independent archive of past surface temperature changes that is complementary to both the instrumental record and the climate proxies. Here we use present-day temperatures in 616 boreholes from all continents except Antarctica to reconstruct century-long trends in temperatures over the past 500 years at global, hemispheric and continental scales. The results confirm the unusual warming of the twentieth century revealed by the instrumental record, but suggest that the cumulative change over the past five centuries amounts to about 1 K, exceeding recent estimates from conventional climate proxies. The strength of temperature reconstructions from boreholes lies in the detection of long-term trends, complementary to conventional climate proxies, but to obtain a complete picture of past warming, the differences between the approaches need to be investigated in detail.
