The SP19 chronology for the South Pole Ice Core – Part 2: gas chronology, Δage, and smoothing of atmospheric records

A new ice core drilled at the South Pole provides a 54 000-year paleoenvironmental record including the composition of the past atmosphere. This paper describes the SP19 chronology for the South Pole atmospheric gas record and complements a previous paper (Winski et al., 2019) describing the SP19 ic...

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Bibliographic Details
Published in:Climate of the Past
Main Authors: Epifanio, Jenna A., Brook, Edward J., Buizert, Christo, Edwards, Jon S., Sowers, Todd A., Kahle, Emma C., Severinghaus, Jeffrey P., Steig, Eric J., Winski, Dominic A., Osterberg, Erich C., Fudge, Tyler J., Aydin, Murat, Hood, Ekaterina, Kalk, Michael, Kreutz, Karl J., Ferris, David G., Kennedy, Joshua A.
Format: Text
Language:English
Published: 2020
Subjects:
Antarctic
South Pole
West Antarctic Ice Sheet
Antarc*
ice core
Ice Sheet
South pole
Online Access:https://doi.org/10.5194/cp-16-2431-2020
https://cp.copernicus.org/articles/16/2431/2020/
Description
Summary:A new ice core drilled at the South Pole provides a 54 000-year paleoenvironmental record including the composition of the past atmosphere. This paper describes the SP19 chronology for the South Pole atmospheric gas record and complements a previous paper (Winski et al., 2019) describing the SP19 ice chronology. The gas chronology is based on a discrete methane (CH 4 ) record with 20- to 190-year resolution. To construct the gas timescale, abrupt changes in atmospheric CH 4 during the glacial period and centennial CH 4 variability during the Holocene were used to synchronize the South Pole gas record with analogous data from the West Antarctic Ice Sheet Divide ice core. Stratigraphic matching based on visual optimization was verified using an automated matching algorithm. The South Pole ice core recovers all expected changes in CH 4 based on previous records. Gas transport in the firn results in smoothing of the atmospheric gas record with a smoothing function spectral width that ranges from 30 to 78 years, equal to 3 % of the gas-age–ice-age difference, or Δ age. The new gas chronology, in combination with the existing ice age scale from Winski et al. (2019), allows a model-independent reconstruction of the gas-age–ice-age difference through the whole record, which will be useful for testing firn densification models.

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