Your search keyword '"Ekaykin, A."' showing total 14 results

1. Estimation of gas record alteration in very low-accumulation ice cores

Author

K. Fourteau, P. Martinerie, X. Faïn, A. A. Ekaykin, J. Chappellaz, and V. Lipenkov

Subjects

Environmental pollution, TD172-193.5, Environmental protection, TD169-171.8, Environmental sciences, GE1-350

Abstract

We measured the methane mixing ratios of enclosed air in five ice core sections drilled on the East Antarctic Plateau. Our work aims to study two effects that alter the recorded gas concentrations in ice cores: layered gas trapping artifacts and firn smoothing. Layered gas trapping artifacts are due to the heterogeneous nature of polar firn, where some strata might close early and trap abnormally old gases that appear as spurious values during measurements. The smoothing is due to the combined effects of diffusive mixing in the firn and the progressive closure of bubbles at the bottom of the firn. Consequently, the gases trapped in a given ice layer span a distribution of ages. This means that the gas concentration in an ice layer is the average value over a certain period of time, which removes the fast variability from the record. Here, we focus on the study of East Antarctic Plateau ice cores, as these low-accumulation ice cores are particularly affected by both layering and smoothing. We use high-resolution methane data to test a simple trapping model reproducing the layered gas trapping artifacts for different accumulation conditions typical of the East Antarctic Plateau. We also use the high-resolution methane measurements to estimate the gas age distributions of the enclosed air in the five newly measured ice core sections. It appears that for accumulations below 2 cm ice equivalent yr−1 the gas records experience nearly the same degree of smoothing. We therefore propose to use a single gas age distribution to represent the firn smoothing observed in the glacial ice cores of the East Antarctic Plateau. Finally, we used the layered gas trapping model and the estimation of glacial firn smoothing to quantify their potential impacts on a hypothetical 1.5-million-year-old ice core from the East Antarctic Plateau. Our results indicate that layering artifacts are no longer individually resolved in the case of very thinned ice near the bedrock. They nonetheless contribute to slight biases of the measured signal (less than 10 ppbv and 0.5 ppmv in the case of methane using our currently established continuous CH4 analysis and carbon dioxide, respectively). However, these biases are small compared to the dampening experienced by the record due to firn smoothing.

Published

2020

2. Analytical constraints on layered gas trapping and smoothing of atmospheric variability in ice under low-accumulation conditions

Author

K. Fourteau, X. Faïn, P. Martinerie, A. Landais, A. A. Ekaykin, V. Ya. Lipenkov, and J. Chappellaz

Subjects

Environmental pollution, TD172-193.5, Environmental protection, TD169-171.8, Environmental sciences, GE1-350

Abstract

We investigate for the first time the loss and alteration of past atmospheric information from air trapping mechanisms under low-accumulation conditions through continuous CH4 (and CO) measurements. Methane concentration changes were measured over the Dansgaard–Oeschger event 17 (DO-17, ∼ 60 000 yr BP) in the Antarctic Vostok 4G-2 ice core. Measurements were performed using continuous-flow analysis combined with laser spectroscopy. The results highlight many anomalous layers at the centimeter scale that are unevenly distributed along the ice core. The anomalous methane mixing ratios differ from those in the immediate surrounding layers by up to 50 ppbv. This phenomenon can be theoretically reproduced by a simple layered trapping model, creating very localized gas age scale inversions. We propose a method for cleaning the record of anomalous values that aims at minimizing the bias in the overall signal. Once the layered-trapping-induced anomalies are removed from the record, DO-17 appears to be smoother than its equivalent record from the high-accumulation WAIS Divide ice core. This is expected due to the slower sinking and densification speeds of firn layers at lower accumulation. However, the degree of smoothing appears surprisingly similar between modern and DO-17 conditions at Vostok. This suggests that glacial records of trace gases from low-accumulation sites in the East Antarctic plateau can provide a better time resolution of past atmospheric composition changes than previously expected. We also developed a numerical method to extract the gas age distributions in ice layers after the removal of the anomalous layers based on comparison with a weakly smoothed record. It is particularly adapted for the conditions of the East Antarctic plateau, as it helps to characterize smoothing for a large range of very low-temperature and low-accumulation conditions.

Published

2017

3. Antarctic climate variability on regional and continental scales over the last 2000 years

Author

B. Stenni, M. A. J. Curran, N. J. Abram, A. Orsi, S. Goursaud, V. Masson-Delmotte, R. Neukom, H. Goosse, D. Divine, T. van Ommen, E. J. Steig, D. A. Dixon, E. R. Thomas, N. A. N. Bertler, E. Isaksson, A. Ekaykin, M. Werner, and M. Frezzotti

Subjects

Environmental pollution, TD172-193.5, Environmental protection, TD169-171.8, Environmental sciences, GE1-350

Abstract

Climate trends in the Antarctic region remain poorly characterized, owing to the brevity and scarcity of direct climate observations and the large magnitude of interannual to decadal-scale climate variability. Here, within the framework of the PAGES Antarctica2k working group, we build an enlarged database of ice core water stable isotope records from Antarctica, consisting of 112 records. We produce both unweighted and weighted isotopic (δ18O) composites and temperature reconstructions since 0 CE, binned at 5- and 10-year resolution, for seven climatically distinct regions covering the Antarctic continent. Following earlier work of the Antarctica2k working group, we also produce composites and reconstructions for the broader regions of East Antarctica, West Antarctica and the whole continent. We use three methods for our temperature reconstructions: (i) a temperature scaling based on the δ18O–temperature relationship output from an ECHAM5-wiso model simulation nudged to ERA-Interim atmospheric reanalyses from 1979 to 2013, and adjusted for the West Antarctic Ice Sheet region to borehole temperature data, (ii) a temperature scaling of the isotopic normalized anomalies to the variance of the regional reanalysis temperature and (iii) a composite-plus-scaling approach used in a previous continent-scale reconstruction of Antarctic temperature since 1 CE but applied to the new Antarctic ice core database. Our new reconstructions confirm a significant cooling trend from 0 to 1900 CE across all Antarctic regions where records extend back into the 1st millennium, with the exception of the Wilkes Land coast and Weddell Sea coast regions. Within this long-term cooling trend from 0 to 1900 CE, we find that the warmest period occurs between 300 and 1000 CE, and the coldest interval occurs from 1200 to 1900 CE. Since 1900 CE, significant warming trends are identified for the West Antarctic Ice Sheet, the Dronning Maud Land coast and the Antarctic Peninsula regions, and these trends are robust across the distribution of records that contribute to the unweighted isotopic composites and also significant in the weighted temperature reconstructions. Only for the Antarctic Peninsula is this most recent century-scale trend unusual in the context of natural variability over the last 2000 years. However, projected warming of the Antarctic continent during the 21st century may soon see significant and unusual warming develop across other parts of the Antarctic continent. The extended Antarctica2k ice core isotope database developed by this working group opens up many avenues for developing a deeper understanding of the response of Antarctic climate to natural and anthropogenic climate forcings. The first long-term quantification of regional climate in Antarctica presented herein is a basis for data–model comparison and assessments of past, present and future driving factors of Antarctic climate.

Published

2017

4. Regional Antarctic snow accumulation over the past 1000 years

Author

E. R. Thomas, J. M. van Wessem, J. Roberts, E. Isaksson, E. Schlosser, T. J. Fudge, P. Vallelonga, B. Medley, J. Lenaerts, N. Bertler, M. R. van den Broeke, D. A. Dixon, M. Frezzotti, B. Stenni, M. Curran, and A. A. Ekaykin

Subjects

Environmental pollution, TD172-193.5, Environmental protection, TD169-171.8, Environmental sciences, GE1-350

Abstract

Here we present Antarctic snow accumulation variability at the regional scale over the past 1000 years. A total of 79 ice core snow accumulation records were gathered and assigned to seven geographical regions, separating the high-accumulation coastal zones below 2000 m of elevation from the dry central Antarctic Plateau. The regional composites of annual snow accumulation were evaluated against modelled surface mass balance (SMB) from RACMO2.3p2 and precipitation from ERA-Interim reanalysis. With the exception of the Weddell Sea coast, the low-elevation composites capture the regional precipitation and SMB variability as defined by the models. The central Antarctic sites lack coherency and either do not represent regional precipitation or indicate the model inability to capture relevant precipitation processes in the cold, dry central plateau. Our results show that SMB for the total Antarctic Ice Sheet (including ice shelves) has increased at a rate of 7 ± 0.13 Gt decade−1 since 1800 AD, representing a net reduction in sea level of ∼ 0.02 mm decade−1 since 1800 and ∼ 0.04 mm decade−1 since 1900 AD. The largest contribution is from the Antarctic Peninsula (∼ 75 %) where the annual average SMB during the most recent decade (2001–2010) is 123 ± 44 Gt yr−1 higher than the annual average during the first decade of the 19th century. Only four ice core records cover the full 1000 years, and they suggest a decrease in snow accumulation during this period. However, our study emphasizes the importance of low-elevation coastal zones, which have been under-represented in previous investigations of temporal snow accumulation.

Published

2017

5. Large-scale drivers of Caucasus climate variability in meteorological records and Mt El'brus ice cores

Author

A. Kozachek, V. Mikhalenko, V. Masson-Delmotte, A. Ekaykin, P. Ginot, S. Kutuzov, M. Legrand, V. Lipenkov, and S. Preunkert

Subjects

Environmental pollution, TD172-193.5, Environmental protection, TD169-171.8, Environmental sciences, GE1-350

Abstract

A 181.8 m ice core was recovered from a borehole drilled into bedrock on the western plateau of Mt El'brus (43°20′53.9′′ N, 42°25′36.0′′ E; 5115 m a.s.l.) in the Caucasus, Russia, in 2009 (Mikhalenko et al., 2015). Here, we report on the results of the water stable isotope composition from this ice core with additional data from the shallow cores. The distinct seasonal cycle of the isotopic composition allows dating by annual layer counting. Dating has been performed for the upper 126 m of the deep core combined with 20 m from the shallow cores. The whole record covers 100 years, from 2013 back to 1914. Due to the high accumulation rate (1380 mm w.e. year−1) and limited melting, we obtained isotopic composition and accumulation rate records with seasonal resolution. These values were compared with available meteorological data from 13 weather stations in the region and also with atmosphere circulation indices, back-trajectory calculations, and Global Network of Isotopes in Precipitation (GNIP) data in order to decipher the drivers of accumulation and ice core isotopic composition in the Caucasus region. In the warm season (May–October) the isotopic composition depends on local temperatures, but the correlation is not persistent over time, while in the cold season (November–April), atmospheric circulation is the predominant driver of the ice core's isotopic composition. The snow accumulation rate correlates well with the precipitation rate in the region all year round, which made it possible to reconstruct and expand the precipitation record at the Caucasus highlands from 1914 until 1966, when reliable meteorological observations of precipitation at high elevation began.

Published

2017

6. Climatic variability in Princess Elizabeth Land (East Antarctica) over the last 350 years

Author

A. A. Ekaykin, D. O. Vladimirova, V. Y. Lipenkov, and V. Masson-Delmotte

Subjects

Environmental pollution, TD172-193.5, Environmental protection, TD169-171.8, Environmental sciences, GE1-350

Abstract

We use isotopic composition (δD) data from six sites in Princess Elizabeth Land (PEL) in order to reconstruct air temperature variability in this sector of East Antarctica over the last 350 years. First, we use the present-day instrumental mean annual surface air temperature data to demonstrate that the studied region (between Russia's Progress, Vostok and Mirny research stations) is characterized by uniform temperature variability. We thus construct a stacked record of the temperature anomaly for the whole sector for the period of 1958–2015. A comparison of this series with the Southern Hemisphere climatic indices shows that the short-term inter-annual temperature variability is primarily governed by the Antarctic Oscillation (AAO) and Interdecadal Pacific Oscillation (IPO) modes of atmospheric variability. However, the low-frequency temperature variability (with period > 27 years) is mainly related to the anomalies of the Indian Ocean Dipole (IOD) mode. We then construct a stacked record of δD for the PEL for the period of 1654–2009 from individual normalized and filtered isotopic records obtained at six different sites (PEL2016 stacked record). We use a linear regression of this record and the stacked PEL temperature record (with an apparent slope of 9 ± 5.4 ‰ °C−1) to convert PEL2016 into a temperature scale. Analysis of PEL2016 shows a 1 ± 0.6 °C warming in this region over the last 3 centuries, with a particularly cold period from the mid-18th to the mid-19th century. A peak of cooling occurred in the 1840s – a feature previously observed in other Antarctic records. We reveal that PEL2016 correlates with a low-frequency component of IOD and suggest that the IOD mode influences the Antarctic climate by modulating the activity of cyclones that bring heat and moisture to Antarctica. We also compare PEL2016 with other Antarctic stacked isotopic records. This work is a contribution to the PAGES (Past Global Changes) and IPICS (International Partnerships in Ice Core Sciences) Antarctica 2k projects.

Published

2017

7. A comparison of the present and last interglacial periods in six Antarctic ice cores

Author

V. Masson-Delmotte, D. Buiron, A. Ekaykin, M. Frezzotti, H. Gallée, J. Jouzel, G. Krinner, A. Landais, H. Motoyama, H. Oerter, K. Pol, D. Pollard, C. Ritz, E. Schlosser, L. C. Sime, H. Sodemann, B. Stenni, R. Uemura, and F. Vimeux

Subjects

Environmental pollution, TD172-193.5, Environmental protection, TD169-171.8, Environmental sciences, GE1-350

Abstract

We compare the present and last interglacial periods as recorded in Antarctic water stable isotope records now available at various temporal resolutions from six East Antarctic ice cores: Vostok, Taylor Dome, EPICA Dome C (EDC), EPICA Dronning Maud Land (EDML), Dome Fuji and the recent TALDICE ice core from Talos Dome. We first review the different modern site characteristics in terms of ice flow, meteorological conditions, precipitation intermittency and moisture origin, as depicted by meteorological data, atmospheric reanalyses and Lagrangian moisture source diagnostics. These different factors can indeed alter the relationships between temperature and water stable isotopes. Using five records with sufficient resolution on the EDC3 age scale, common features are quantified through principal component analyses. Consistent with instrumental records and atmospheric model results, the ice core data depict rather coherent and homogenous patterns in East Antarctica during the last two interglacials. Across the East Antarctic plateau, regional differences, with respect to the common East Antarctic signal, appear to have similar patterns during the current and last interglacials. We identify two abrupt shifts in isotopic records during the glacial inception at TALDICE and EDML, likely caused by regional sea ice expansion. These regional differences are discussed in terms of moisture origin and in terms of past changes in local elevation histories, which are compared to ice sheet model results. Our results suggest that elevation changes may contribute significantly to inter-site differences. These elevation changes may be underestimated by current ice sheet models.

Published

2011

8. Estimation of gas record alteration in very low-accumulation ice cores

Author

Fourteau, Kévin, primary, Martinerie, Patricia, additional, Faïn, Xavier, additional, Ekaykin, Alexey A., additional, Chappellaz, Jérôme, additional, and Lipenkov, Vladimir, additional

Published

2020

9. Analytical constraints on layered gas trapping and smoothing of atmospheric variability in ice under low-accumulation conditions

Author

Fourteau, Kévin, primary, Faïn, Xavier, additional, Martinerie, Patricia, additional, Landais, Amaëlle, additional, Ekaykin, Alexey A., additional, Lipenkov, Vladimir Ya., additional, and Chappellaz, Jérôme, additional

Published

2017

10. Antarctic climate variability on regional and continental scales over the last 2000 years

Author

Stenni, Barbara, primary, Curran, Mark A. J., additional, Abram, Nerilie J., additional, Orsi, Anais, additional, Goursaud, Sentia, additional, Masson-Delmotte, Valerie, additional, Neukom, Raphael, additional, Goosse, Hugues, additional, Divine, Dmitry, additional, van Ommen, Tas, additional, Steig, Eric J., additional, Dixon, Daniel A., additional, Thomas, Elizabeth R., additional, Bertler, Nancy A. N., additional, Isaksson, Elisabeth, additional, Ekaykin, Alexey, additional, Werner, Martin, additional, and Frezzotti, Massimo, additional

Published

2017

11. Regional Antarctic snow accumulation over the past 1000 years

Author

Thomas, Elizabeth R., primary, van Wessem, J. Melchior, additional, Roberts, Jason, additional, Isaksson, Elisabeth, additional, Schlosser, Elisabeth, additional, Fudge, Tyler J., additional, Vallelonga, Paul, additional, Medley, Brooke, additional, Lenaerts, Jan, additional, Bertler, Nancy, additional, van den Broeke, Michiel R., additional, Dixon, Daniel A., additional, Frezzotti, Massimo, additional, Stenni, Barbara, additional, Curran, Mark, additional, and Ekaykin, Alexey A., additional

Published

2017

12. Large-scale drivers of Caucasus climate variability in meteorological records and Mt El'brus ice cores

Author

Kozachek, Anna, primary, Mikhalenko, Vladimir, additional, Masson-Delmotte, Valérie, additional, Ekaykin, Alexey, additional, Ginot, Patrick, additional, Kutuzov, Stanislav, additional, Legrand, Michel, additional, Lipenkov, Vladimir, additional, and Preunkert, Susanne, additional

Published

2017

13. Climatic variability in Princess Elizabeth Land (East Antarctica) over the last 350 years

Author

Ekaykin, Alexey A., primary, Vladimirova, Diana O., additional, Lipenkov, Vladimir Y., additional, and Masson-Delmotte, Valérie, additional

Published

2017

14. A comparison of the present and last interglacial periods in six Antarctic ice cores

Author

Masson-Delmotte, V., primary, Buiron, D., additional, Ekaykin, A., additional, Frezzotti, M., additional, Gallée, H., additional, Jouzel, J., additional, Krinner, G., additional, Landais, A., additional, Motoyama, H., additional, Oerter, H., additional, Pol, K., additional, Pollard, D., additional, Ritz, C., additional, Schlosser, E., additional, Sime, L. C., additional, Sodemann, H., additional, Stenni, B., additional, Uemura, R., additional, and Vimeux, F., additional

Published

2011