During the first half of the nineteenth century, several large tropical volcanic eruptions occurred within less than three decades. The global climate effects of the 1815 Tambora eruption have been investigated, but those of an eruption in 1808 or 1809 whose source is unknown and the eruptions in the 1820s and 1830s have received less attention. Here we analyse the effect of the sequence of eruptions in observations, global three-dimensional climate field reconstructions and coupled climate model simulations. All the eruptions were followed by substantial drops of summer temperature over the Northern Hemisphere land areas. In addition to the direct radiative effect, which lasts 2–3 years, the simulated ocean–atmosphere heat exchange sustained cooling for several years after these eruptions, which affected the slow components of the climate system. Africa was hit by two decades of drought, global monsoons weakened and the tracks of low-pressure systems over the North Atlantic moved south. The low temperatures and increased precipitation in Europe triggered the last phase of the advance of Alpine glaciers. Only after the 1850s did the transition into the period of anthropogenic warming start. We conclude that the end of the Little Ice Age was marked by the recovery from a sequence of volcanic eruptions, which makes it difficult to define a single pre-industrial baseline.
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The palaeo-reanalysis is available from http://cera-www.dkrz.de/WDCC/ui/Compact.jsp?acronym=EKF400_v1.1 and instrumental temperature data from https://www.ncdc.noaa.gov/ghcnm/v3.php. The dryness indices for Africa are available from https://www1.ncdc.noaa.gov/pub/data/paleo/historical/africa/africa2001precip.txt and the Australian monsoon data from https://www.upo.es/vareclim/Data/Data_Index.php. The pressure data used are available from ISPD, https://reanalyses.org/observations/international-surface-pressure-databank. FUPSOL and HadCM3 model output can be downloaded from https://boris.unibe.ch/131129/.
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The work was supported by the Swiss National Science Foundation (projects 162668, 169676, CRSII2-147659 and a personal grant to M.T.), by MeteoSwiss (CH2018) and by H2020 (ERC Grant PALAEO-RA, 787574). Simulations were conducted at the Swiss Supercomputer Centre CSCS. G.C.H. and A.S. were supported by the ERC-funded project TITAN (EC-320691) and by NERC under the Belmont forum, grant PacMedy (NE/P006752/1).
The authors declare no competing interests.
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Consistent multidecadal variability in global temperature reconstructions and simulations over the Common Era
Nature Geoscience (2019)
Climate of the Past (2019)