Methane (CH₄), the second most important anthropogenic greenhouse gas, has increased in the atmosphere by a factor 2.5 since the onset of the Industrial Revolution, which account for ~20% of the total increase in radiative forcing over that time^[1]. Ice cores from both polar regions preserve the past atmospheric CH₄, and thus have the potential to constrain the changes in CH₄ concentration difference between the polar regions. The inter polar difference of CH₄ is one of the approaches to understand the evolution of CH₄ budget and its relationship with climate. To reconstruct the CH₄ inter polar difference during the Holocene, we have been measuring CH₄ concentrations in the NEEM (Greenland) and Dome Fuji (Antarctica) ice cores over the period from 200 to 14500 years before present (yr BP), with a mean time resolution of ~50 years. Since most of this time period is overlapping with the brittle zone in the Greenland core, it is challenging to reconstruct accurate CH₄ concentration during the Holocene from the NEEM ice core.
Ice samples without visible cracks were carefully selected from the NEEM and Dome Fuji ice cores. We employed a newly established wet extraction system (an improved version of ref. 2) the National Institute of Polar Research, with a typical sample size of ~80 g (ice). The air released from ice was first collected into a sample tube (electropolished stainless steel tube with a metal-seal valve), and then it was split into two aliquots. One aliquot was measured by a gas chromatograph (Agilent Technologies 7890A) for CO₂, CH₄ and N₂O concentrations, and the other was measured by a mass spectrometer (Thermo DELTA V Plus) for δ¹⁵N of N₂, δ¹⁸O of O₂, δ(O₂/N₂), δ(Ar/N₂) and total air content. We have measured 181 samples for the NEEM ice core. Analytical precision of CH₄ concentration was estimated to be ±2.4 ppb from the pooled standard deviation from duplicate measurements (n=53).
Before the Holocene, the NEEM CH₄ concentration is relatively high (620-705 ppb) during the Bølling-Allerød, and it rapidly decreases to <500 ppb during the Younger Dryas, and then increases to ~750 ppb at the beginning of the Holocene. During the Holocene, CH₄ concentration first decreases to the minimum of ~610 ppb around 5000 yr BP, and it increases afterwards. Our record agrees well with a high resolution CH₄ concentration record from the GISP2 ice core for last 2000 years^[3], and that of the NEEM ice core measured by a CFA system between 9500 and 14500 yr BP^[4].
We completed the NEEM measurements and started the Dome Fuji measurements, and the resulting CH4 inter polar difference will be deduced and discussed in the presentation.
References
[1] P. Forster et al., in Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, S. Solomon et al., Eds. (Cambridge Univ. Press, Cambridge, 2007), pp. 131–234.
[2] Kawamura et al. (2003). Atmospheric CO₂ variations over the last three glacial-interglacial climatic cycles deduced from the Dome Fuji deep ice core, Antarctica using a wet extraction technique. Tellus B, 55(2), 126–137.
[3] Mitchell et al. (2013). Constraints on the Late Holocene Anthropogenic Contribution to the Atmospheric Methane Budget. Science, 342(6161), 964–966.
[4] Chappellaz et al. (2013). High-resolution glacial and deglacial record of atmospheric methane by continuous-flow and laser spectrometer analysis along the NEEM ice core. Clim. Past, 9(6), 2579–2593.