Abstract
Abstract. Orbital tuning is central for ice core chronologies beyond annual layer counting, available back to 60 ka (i.e. thousands of years before 1950) for Greenland ice cores. While several complementary orbital tuning tools have recently been developed using δ18Oatm, δO2⁄N2 and air content with different orbital targets, quantifying their uncertainties remains a challenge. Indeed, the exact processes linking variations of these parameters, measured in the air trapped in ice, to their orbital targets are not yet fully understood. Here, we provide new series of δO2∕N2 and δ18Oatm data encompassing Marine Isotopic Stage (MIS) 5 (between 100 and 160 ka) and the oldest part (340–800 ka) of the East Antarctic EPICA Dome C (EDC) ice core. For the first time, the measurements over MIS 5 allow an inter-comparison of δO2∕N2 and δ18Oatm records from three East Antarctic ice core sites (EDC, Vostok and Dome F). This comparison highlights some site-specific δO2∕N2 variations. Such an observation, the evidence of a 100 ka periodicity in the δO2∕N2 signal and the difficulty to identify extrema and mid-slopes in δO2∕N2 increase the uncertainty associated with the use of δO2∕N2 as an orbital tuning tool, now calculated to be 3–4 ka. When combining records of δ18Oatm and δO2∕N2 from Vostok and EDC, we find a loss of orbital signature for these two parameters during periods of minimum eccentricity (∼ 400 ka, ∼ 720–800 ka). Our data set reveals a time-varying offset between δO2∕N2 and δ18Oatm records over the last 800 ka that we interpret as variations in the lagged response of δ18Oatm to precession. The largest offsets are identified during Terminations II, MIS 8 and MIS 16, corresponding to periods of destabilization of the Northern polar ice sheets. We therefore suggest that the occurrence of Heinrich–like events influences the response of δ18Oatm to precession.
Highlights
Past changes in climate and atmospheric composition are recorded in a variety of ice core proxies
We argue that the large variations of the lag observed between δO2/N2 and δ18Oatm are mainly due to variations in the relationship between δ18Oatm and precession as (1) there is nearly no differences in timing of insolation and precession variations, and (2) δO2/N2 can be considered synchronous at first order with local insolation
We have presented new measurements of δO2/N2 and δ18Oatm performed on well-conserved ice from EPICA Dome C (EDC) over Marine Isotope Stage (MIS) 5 and between 340 and 800 ka
Summary
Past changes in climate and atmospheric composition are recorded in a variety of ice core proxies. Records of δO2/N2 and air content measured at Vostok, Dome F and EDC depict variability at orbital frequencies, which appears in phase with local summer insolation (Bender, 2002; Kawamura et al, 2007; Raynaud et al, 2007; Lipenkov et al, 2011; Landais et al, 2012). Air content and δO2/N2 provide a relationship between the ice phase age and local insolation, due to the impact of snow metamorphism on air trapping processes These three dating tools have limitations as detailed below. The limitations associated with the use of δO2/N2, δ18Oatm and air content have recently motivated a first assessment of the coherency between the different orbital dating tools in ice cores. The records of δ18Oatm and δO2/N2 enable us to check the coherency of these parameters for orbital tuning and to provide recommendations for their use for ice core chronology building
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