CO2 and O2/N2 variations in and just below the bubble–clathrate transformation zone of Antarctic ice cores

Dieter Lüthi; Bernhard Bereiter; Bernhard Stauffer; R. Winkler; Jakob Schwander; P. Kindler; M. Leuenberger; S. Kipfstuhl; Emilie Capron; Amaelle Landais; H. Fischer; T. Stocker

doi:10.1016/j.epsl.2010.06.023

CO2 and O2/N2 variations in and just below the bubble–clathrate transformation zone of Antarctic ice cores

Dieter Lüthi, Bernhard Bereiter, Bernhard Stauffer, R. Winkler, Jakob Schwander, P. Kindler, M. Leuenberger, S. Kipfstuhl, Emilie Capron, Amaelle Landais, H. Fischer, T. Stocker

29 Citations (Scopus)

Abstract

CO₂ measurements on the EPICA (European Project for Ice Coring in Antarctica) DML ice core in depth levels just below the bubble ice-clathrate ice transformation zone (1230-2240m depth) were performed. In the youngest part (1230-1600m), they reveal variations of up to 25ppmv around the mean atmospheric concentration within centimetres, corresponding to a snow deposition interval of a few years. Similar results are found at corresponding depth regions of the Dome C and the Talos Dome ice cores. Since we can exclude all hitherto known processes altering the concentration of CO₂ in ice cores, we present a hypothesis about spatial fractionation of air components related to episodically increasing clathrate formation followed by diffusion processes from bubbles to clathrates. This hypothesis is supported by optical line-scan observations and by O₂/N₂ measurements at the same depth where strong CO₂ variations are detected. Below the clathrate formation zone, this small-scale fractionation process is slowly smoothed out, most likely by diffusion, regaining the initial mean atmospheric concentration. Although this process compromises the representativeness of a single CO₂ measurement on small ice samples in the clathrate formation zone of an ice core, it does not affect the mean atmospheric CO₂ concentration if CO₂ values are averaged over a sufficiently long depth scale (>10cm in case of the EPICA DML ice core).

Original language	English
Journal	Earth Planetary Science Letters
Volume	1-2
Pages (from-to)	226-233
ISSN	0012-821X
DOIs	https://doi.org/10.1016/j.epsl.2010.06.023
Publication status	Published - 15 Aug 2010
Externally published	Yes

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Lüthi, D., Bereiter, B., Stauffer, B., Winkler, R., Schwander, J., Kindler, P., Leuenberger, M., Kipfstuhl, S., Capron, E., Landais, A., Fischer, H., & Stocker, T. (2010). CO2 and O2/N2 variations in and just below the bubble–clathrate transformation zone of Antarctic ice cores. Earth Planetary Science Letters, 1-2, 226-233. https://doi.org/10.1016/j.epsl.2010.06.023

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title = "CO2 and O2/N2 variations in and just below the bubble–clathrate transformation zone of Antarctic ice cores",

abstract = "CO2 measurements on the EPICA (European Project for Ice Coring in Antarctica) DML ice core in depth levels just below the bubble ice-clathrate ice transformation zone (1230-2240m depth) were performed. In the youngest part (1230-1600m), they reveal variations of up to 25ppmv around the mean atmospheric concentration within centimetres, corresponding to a snow deposition interval of a few years. Similar results are found at corresponding depth regions of the Dome C and the Talos Dome ice cores. Since we can exclude all hitherto known processes altering the concentration of CO2 in ice cores, we present a hypothesis about spatial fractionation of air components related to episodically increasing clathrate formation followed by diffusion processes from bubbles to clathrates. This hypothesis is supported by optical line-scan observations and by O2/N2 measurements at the same depth where strong CO2 variations are detected. Below the clathrate formation zone, this small-scale fractionation process is slowly smoothed out, most likely by diffusion, regaining the initial mean atmospheric concentration. Although this process compromises the representativeness of a single CO2 measurement on small ice samples in the clathrate formation zone of an ice core, it does not affect the mean atmospheric CO2 concentration if CO2 values are averaged over a sufficiently long depth scale (>10cm in case of the EPICA DML ice core).",

author = "Dieter L{\"u}thi and Bernhard Bereiter and Bernhard Stauffer and R. Winkler and Jakob Schwander and P. Kindler and M. Leuenberger and S. Kipfstuhl and Emilie Capron and Amaelle Landais and H. Fischer and T. Stocker",

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doi = "10.1016/j.epsl.2010.06.023",

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T1 - CO2 and O2/N2 variations in and just below the bubble–clathrate transformation zone of Antarctic ice cores

AU - Lüthi, Dieter

AU - Bereiter, Bernhard

AU - Stauffer, Bernhard

AU - Winkler, R.

AU - Schwander, Jakob

AU - Kindler, P.

AU - Leuenberger, M.

AU - Kipfstuhl, S.

AU - Capron, Emilie

AU - Landais, Amaelle

AU - Fischer, H.

AU - Stocker, T.

PY - 2010/8/15

Y1 - 2010/8/15

N2 - CO2 measurements on the EPICA (European Project for Ice Coring in Antarctica) DML ice core in depth levels just below the bubble ice-clathrate ice transformation zone (1230-2240m depth) were performed. In the youngest part (1230-1600m), they reveal variations of up to 25ppmv around the mean atmospheric concentration within centimetres, corresponding to a snow deposition interval of a few years. Similar results are found at corresponding depth regions of the Dome C and the Talos Dome ice cores. Since we can exclude all hitherto known processes altering the concentration of CO2 in ice cores, we present a hypothesis about spatial fractionation of air components related to episodically increasing clathrate formation followed by diffusion processes from bubbles to clathrates. This hypothesis is supported by optical line-scan observations and by O2/N2 measurements at the same depth where strong CO2 variations are detected. Below the clathrate formation zone, this small-scale fractionation process is slowly smoothed out, most likely by diffusion, regaining the initial mean atmospheric concentration. Although this process compromises the representativeness of a single CO2 measurement on small ice samples in the clathrate formation zone of an ice core, it does not affect the mean atmospheric CO2 concentration if CO2 values are averaged over a sufficiently long depth scale (>10cm in case of the EPICA DML ice core).

AB - CO2 measurements on the EPICA (European Project for Ice Coring in Antarctica) DML ice core in depth levels just below the bubble ice-clathrate ice transformation zone (1230-2240m depth) were performed. In the youngest part (1230-1600m), they reveal variations of up to 25ppmv around the mean atmospheric concentration within centimetres, corresponding to a snow deposition interval of a few years. Similar results are found at corresponding depth regions of the Dome C and the Talos Dome ice cores. Since we can exclude all hitherto known processes altering the concentration of CO2 in ice cores, we present a hypothesis about spatial fractionation of air components related to episodically increasing clathrate formation followed by diffusion processes from bubbles to clathrates. This hypothesis is supported by optical line-scan observations and by O2/N2 measurements at the same depth where strong CO2 variations are detected. Below the clathrate formation zone, this small-scale fractionation process is slowly smoothed out, most likely by diffusion, regaining the initial mean atmospheric concentration. Although this process compromises the representativeness of a single CO2 measurement on small ice samples in the clathrate formation zone of an ice core, it does not affect the mean atmospheric CO2 concentration if CO2 values are averaged over a sufficiently long depth scale (>10cm in case of the EPICA DML ice core).

U2 - 10.1016/j.epsl.2010.06.023

DO - 10.1016/j.epsl.2010.06.023

M3 - Journal article

SN - 0012-821X

VL - 1-2

SP - 226

EP - 233

JO - Earth and Planetary Science Letters

JF - Earth and Planetary Science Letters

ER -

CO2 and O2/N2 variations in and just below the bubble–clathrate transformation zone of Antarctic ice cores

Abstract

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