Journal of Glaciology (Aug 2023)

Prefacing unexplored archives from Central Andean surface-to-bedrock ice cores through a multifaceted investigation of regional firn and ice core glaciochemistry

  • Heather M. Clifford,
  • Mariusz Potocki,
  • Charles Rodda,
  • Daniel Dixon,
  • Sean Birkel,
  • Michael Handley,
  • Elena Korotkikh,
  • Douglas Introne,
  • Franciele Schwanck,
  • Flavia A. Tavares,
  • Ronaldo T. Bernardo,
  • Filipe G. L. Lindau,
  • Oscar Vilca Gomez,
  • Harrison Jara-Infantes,
  • Victor Bustínza Urviola,
  • L. Baker Perry,
  • Jonathan Maurer,
  • Anton Seimon,
  • Margit Schwikowski,
  • Gino Casassa,
  • Shugui Hou,
  • Andrei V. Kurbatov,
  • Kimberley R. Miner,
  • Jefferson C. Simões,
  • Paul A. Mayewski

DOI
https://doi.org/10.1017/jog.2022.91
Journal volume & issue
Vol. 69
pp. 693 – 707

Abstract

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Shallow firn cores, in addition to a near-basal ice core, were recovered in 2018 from the Quelccaya ice cap (5470 m a.s.l) in the Cordillera Vilcanota, Peru, and in 2017 from the Nevado Illimani glacier (6350 m a.s.l) in the Cordillera Real, Bolivia. The two sites are ~450 km apart. Despite meltwater percolation resulting from warming, particle-based trace element records (e.g. Fe, Mg, K) in the Quelccaya and Illimani shallow cores retain well-preserved signals. The firn core chronologies, established independently by annual layer counting, show a convincing overlap indicating the two records contain comparable signals and therefore capture similar regional scale climatology. Trace element records at a ~1–4 cm resolution provide past records of anthropogenic emissions, dust sources, volcanic emissions, evaporite salts and marine-sourced air masses. Using novel ultra-high-resolution (120 μm) laser technology, we identify annual layer thicknesses ranging from 0.3 to 0.8 cm in a section of 2000-year-old radiocarbon-dated near-basal ice which compared to the previous annual layer estimates suggests that Quelccaya ice cores drilled to bedrock may be older than previously suggested by depth-age models. With the information collected from this study in combination with past studies, we emphasize the importance of collecting new surface-to-bedrock ice cores from at least the Quelccaya ice cap, in particular, due to its projected disappearance as soon as the 2050s.

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