Climate of the Past (Mar 2024)

Reconstructing hydroclimate changes over the past 2500 years using speleothems from Pyrenean caves (NE Spain)

  • M. Bartolomé,
  • M. Bartolomé,
  • M. Bartolomé,
  • A. Moreno,
  • C. Sancho,
  • I. Cacho,
  • H. Stoll,
  • N. Haghipour,
  • N. Haghipour,
  • Á. Belmonte,
  • C. Spötl,
  • J. Hellstrom,
  • R. L. Edwards,
  • H. Cheng,
  • H. Cheng,
  • H. Cheng

DOI
https://doi.org/10.5194/cp-20-467-2024
Journal volume & issue
Vol. 20
pp. 467 – 494

Abstract

Read online

Reconstructing of past hydroclimates at regional scales during the Common Era (CE) is necessary to place the current warming in the context of natural climate variability. Here we present a composite record of oxygen isotope variations during last 2500 years based on eight stalagmites from four caves in the central Pyrenees (NE Spain) dominated by temperature variations, with the amount of precipitation playing a minor role. The dataset is compared with other Iberian reconstructions that show a high degree of internal coherence with respect to variability at the centennial scale. The Roman Period (RP) (especially 0–200 CE), the Medieval Climate Anomaly (MCA), and part of the Little Ice Age (LIA) represent the warmest periods, while the coldest decades occurred during the Dark Ages (DA) and most of the LIA intervals (e.g., 520–550 CE and 1800–1850 CE). Importantly, the LIA cooling or the MCA warming were not continuous or uniform and exhibited high decadal variability. The Industrial Era (IE) shows an overall warming trend although with marked cycles and partial stabilization during the last 2 decades (1990–2010). The strong coherence between the speleothem data, European temperature reconstructions and global tree-ring data informs about the regional representativeness of this new record as Pyrenean past climate variations. Solar variability, likely through its impact on the North Atlantic Oscillation, and major volcanic eruptions appear to be the two main drivers of climate in southwestern Europe during the past 2.5 millennia.