Observing and modeling the influence of layering on bubble trapping in polar firn

Logan E. Mitchell; Christo Buizert; Edward J. Brook; Daniel J. Breton; John Fegyveresi; Daniel Baggenstos; Anais Orsi; Jeffrey Severinghaus; Richard B. Alley; Mary Albert; Rachael H. Rhodes; Joseph R. McConnell; Michael Sigl; Olivia Maselli; Stephanie Gregory; Jinho Ahn

doi:10.1002/2014JD022766

Observing and modeling the influence of layering on bubble trapping in polar firn

Logan E. Mitchell, Christo Buizert, Edward J. Brook, Daniel J. Breton, John Fegyveresi, Daniel Baggenstos, Anais Orsi, Jeffrey Severinghaus, Richard B. Alley, Mary Albert, Rachael H. Rhodes, Joseph R. McConnell, Michael Sigl, Olivia Maselli, Stephanie Gregory, Jinho Ahn

Geosciences

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31 Scopus citations

Abstract

Interpretation of ice core trace gas records depends on an accurate understanding of the processes that smooth the atmospheric signal in the firn. Much work has been done to understand the processes affecting air transport in the open pores of the firn, but a paucity of data from air trapped in bubbles in the firn-ice transition region has limited the ability to constrain the effect of bubble closure processes. Here we present high-resolution measurements of firn density, methane concentrations, nitrogen isotopes, and total air content that show layering in the firn-ice transition region at the West Antarctic Ice Sheet (WAIS) Divide ice core site. Using the notion that bubble trapping is a stochastic process, we derive a new parameterization for closed porosity that incorporates the effects of layering in a steady state firn modeling approach. We include the process of bubble trapping into an open-porosity firn air transport model and obtain a good fit to the firn core data. We find that layering broadens the depth range over which bubbles are trapped, widens the modeled gas age distribution of air in closed bubbles, reduces the mean gas age of air in closed bubbles, and introduces stratigraphic irregularities in the gas age scale that have a peak-to-peak variability of ~10 years at WAIS Divide. For a more complete understanding of gas occlusion and its impact on ice core records, we suggest that this experiment be repeated at sites climatically different from WAIS Divide, for example, on the East Antarctic plateau.

Original language	English (US)
Pages (from-to)	2558-2574
Number of pages	17
Journal	Journal of Geophysical Research
Volume	120
Issue number	6
DOIs	https://doi.org/10.1002/2014JD022766
State	Published - 2015

All Science Journal Classification (ASJC) codes

Condensed Matter Physics
Materials Chemistry
Polymers and Plastics
Physical and Theoretical Chemistry

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10.1002/2014JD022766

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Mitchell, L. E., Buizert, C., Brook, E. J., Breton, D. J., Fegyveresi, J., Baggenstos, D., Orsi, A., Severinghaus, J., Alley, R. B., Albert, M., Rhodes, R. H., McConnell, J. R., Sigl, M., Maselli, O., Gregory, S., & Ahn, J. (2015). Observing and modeling the influence of layering on bubble trapping in polar firn. Journal of Geophysical Research, 120(6), 2558-2574. https://doi.org/10.1002/2014JD022766

@article{770892e13c5845168c6a96b14f5d2de7,

title = "Observing and modeling the influence of layering on bubble trapping in polar firn",

abstract = "Interpretation of ice core trace gas records depends on an accurate understanding of the processes that smooth the atmospheric signal in the firn. Much work has been done to understand the processes affecting air transport in the open pores of the firn, but a paucity of data from air trapped in bubbles in the firn-ice transition region has limited the ability to constrain the effect of bubble closure processes. Here we present high-resolution measurements of firn density, methane concentrations, nitrogen isotopes, and total air content that show layering in the firn-ice transition region at the West Antarctic Ice Sheet (WAIS) Divide ice core site. Using the notion that bubble trapping is a stochastic process, we derive a new parameterization for closed porosity that incorporates the effects of layering in a steady state firn modeling approach. We include the process of bubble trapping into an open-porosity firn air transport model and obtain a good fit to the firn core data. We find that layering broadens the depth range over which bubbles are trapped, widens the modeled gas age distribution of air in closed bubbles, reduces the mean gas age of air in closed bubbles, and introduces stratigraphic irregularities in the gas age scale that have a peak-to-peak variability of ~10 years at WAIS Divide. For a more complete understanding of gas occlusion and its impact on ice core records, we suggest that this experiment be repeated at sites climatically different from WAIS Divide, for example, on the East Antarctic plateau.",

author = "Mitchell, {Logan E.} and Christo Buizert and Brook, {Edward J.} and Breton, {Daniel J.} and John Fegyveresi and Daniel Baggenstos and Anais Orsi and Jeffrey Severinghaus and Alley, {Richard B.} and Mary Albert and Rhodes, {Rachael H.} and McConnell, {Joseph R.} and Michael Sigl and Olivia Maselli and Stephanie Gregory and Jinho Ahn",

note = "Funding Information: This work was supported by NSF OPP grants 0538578, 0520523, 0538538, 0944343 (to J.P.S.), 0944078 (to M.R.A.), 1142166 (to J.R.M.), and 1043528 (to R.B.A.), the NASA/Oregon Space Grant Consortium grant NNG05GJ85H (to L.E.M.), the NOAA Climate and Global Change Fellowship Program, administered by the University Corporation for Atmospheric Research (to C.B.), and the Polar Academic Program (PAP, PD12010) of Korea Polar Research Institute (KOPRI). We thank Brendan Williams, James Lee, and Jon Edwards for assisting in sample preparation and analysis at OSU; N. Chellman and L. Layman for help in the continuous analyses at DRI; Max Stevens for checking the porosity parameterization equations; Jakob Schwander and David Etheridge for useful discussions and sharing porosity data; Steve Montzka for sharing WAIS halocarbon firn air data; the University of Wisconsin-Madison Automatic Weather Station Program for the surface pressure observations from Kominko-Slade AWS (NSF grants ANT-0944018 and ANT-1245663); two anonymous reviewers for constructive comments which improved the clarity of the manuscript; the WAIS Divide Science Coordination Office at DRI, Reno, Nevada, for the collection and distribution of the WAIS Divide ice core (Kendrick Taylor, NSF grants 0230396, 0440817, 0944348, and 0944266— University of New Hampshire); NSF OPP which funds the Ice Drilling Program Office and Ice Drilling Design and Operations group for coring activities; NSF which funds the National Ice Core Laboratory which curated and processed the core; Raytheon Polar Services which provided logistics support in Antarctica; and the 109th New York Air National Guard for airlift in Antarctica. Data and description can be downloaded from the NOAA National Climate Data Center http://www.ncdc.noaa.gov/data-access/ paleoclimatology-data. Publisher Copyright: {\textcopyright} 2015. American Geophysical Union. All Rights Reserved.",

year = "2015",

doi = "10.1002/2014JD022766",

language = "English (US)",

volume = "120",

pages = "2558--2574",

journal = "Journal of Geophysical Research",

issn = "0148-0227",

number = "6",

}

Mitchell, LE, Buizert, C, Brook, EJ, Breton, DJ, Fegyveresi, J, Baggenstos, D, Orsi, A, Severinghaus, J, Alley, RB, Albert, M, Rhodes, RH, McConnell, JR, Sigl, M, Maselli, O, Gregory, S & Ahn, J 2015, 'Observing and modeling the influence of layering on bubble trapping in polar firn', Journal of Geophysical Research, vol. 120, no. 6, pp. 2558-2574. https://doi.org/10.1002/2014JD022766

TY - JOUR

T1 - Observing and modeling the influence of layering on bubble trapping in polar firn

AU - Mitchell, Logan E.

AU - Buizert, Christo

AU - Brook, Edward J.

AU - Breton, Daniel J.

AU - Fegyveresi, John

AU - Baggenstos, Daniel

AU - Orsi, Anais

AU - Severinghaus, Jeffrey

AU - Alley, Richard B.

AU - Albert, Mary

AU - Rhodes, Rachael H.

AU - McConnell, Joseph R.

AU - Sigl, Michael

AU - Maselli, Olivia

AU - Gregory, Stephanie

AU - Ahn, Jinho

N1 - Funding Information: This work was supported by NSF OPP grants 0538578, 0520523, 0538538, 0944343 (to J.P.S.), 0944078 (to M.R.A.), 1142166 (to J.R.M.), and 1043528 (to R.B.A.), the NASA/Oregon Space Grant Consortium grant NNG05GJ85H (to L.E.M.), the NOAA Climate and Global Change Fellowship Program, administered by the University Corporation for Atmospheric Research (to C.B.), and the Polar Academic Program (PAP, PD12010) of Korea Polar Research Institute (KOPRI). We thank Brendan Williams, James Lee, and Jon Edwards for assisting in sample preparation and analysis at OSU; N. Chellman and L. Layman for help in the continuous analyses at DRI; Max Stevens for checking the porosity parameterization equations; Jakob Schwander and David Etheridge for useful discussions and sharing porosity data; Steve Montzka for sharing WAIS halocarbon firn air data; the University of Wisconsin-Madison Automatic Weather Station Program for the surface pressure observations from Kominko-Slade AWS (NSF grants ANT-0944018 and ANT-1245663); two anonymous reviewers for constructive comments which improved the clarity of the manuscript; the WAIS Divide Science Coordination Office at DRI, Reno, Nevada, for the collection and distribution of the WAIS Divide ice core (Kendrick Taylor, NSF grants 0230396, 0440817, 0944348, and 0944266— University of New Hampshire); NSF OPP which funds the Ice Drilling Program Office and Ice Drilling Design and Operations group for coring activities; NSF which funds the National Ice Core Laboratory which curated and processed the core; Raytheon Polar Services which provided logistics support in Antarctica; and the 109th New York Air National Guard for airlift in Antarctica. Data and description can be downloaded from the NOAA National Climate Data Center http://www.ncdc.noaa.gov/data-access/ paleoclimatology-data. Publisher Copyright: © 2015. American Geophysical Union. All Rights Reserved.

PY - 2015

Y1 - 2015

N2 - Interpretation of ice core trace gas records depends on an accurate understanding of the processes that smooth the atmospheric signal in the firn. Much work has been done to understand the processes affecting air transport in the open pores of the firn, but a paucity of data from air trapped in bubbles in the firn-ice transition region has limited the ability to constrain the effect of bubble closure processes. Here we present high-resolution measurements of firn density, methane concentrations, nitrogen isotopes, and total air content that show layering in the firn-ice transition region at the West Antarctic Ice Sheet (WAIS) Divide ice core site. Using the notion that bubble trapping is a stochastic process, we derive a new parameterization for closed porosity that incorporates the effects of layering in a steady state firn modeling approach. We include the process of bubble trapping into an open-porosity firn air transport model and obtain a good fit to the firn core data. We find that layering broadens the depth range over which bubbles are trapped, widens the modeled gas age distribution of air in closed bubbles, reduces the mean gas age of air in closed bubbles, and introduces stratigraphic irregularities in the gas age scale that have a peak-to-peak variability of ~10 years at WAIS Divide. For a more complete understanding of gas occlusion and its impact on ice core records, we suggest that this experiment be repeated at sites climatically different from WAIS Divide, for example, on the East Antarctic plateau.

AB - Interpretation of ice core trace gas records depends on an accurate understanding of the processes that smooth the atmospheric signal in the firn. Much work has been done to understand the processes affecting air transport in the open pores of the firn, but a paucity of data from air trapped in bubbles in the firn-ice transition region has limited the ability to constrain the effect of bubble closure processes. Here we present high-resolution measurements of firn density, methane concentrations, nitrogen isotopes, and total air content that show layering in the firn-ice transition region at the West Antarctic Ice Sheet (WAIS) Divide ice core site. Using the notion that bubble trapping is a stochastic process, we derive a new parameterization for closed porosity that incorporates the effects of layering in a steady state firn modeling approach. We include the process of bubble trapping into an open-porosity firn air transport model and obtain a good fit to the firn core data. We find that layering broadens the depth range over which bubbles are trapped, widens the modeled gas age distribution of air in closed bubbles, reduces the mean gas age of air in closed bubbles, and introduces stratigraphic irregularities in the gas age scale that have a peak-to-peak variability of ~10 years at WAIS Divide. For a more complete understanding of gas occlusion and its impact on ice core records, we suggest that this experiment be repeated at sites climatically different from WAIS Divide, for example, on the East Antarctic plateau.

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U2 - 10.1002/2014JD022766

DO - 10.1002/2014JD022766

M3 - Article

AN - SCOPUS:84927635917

SN - 0148-0227

VL - 120

SP - 2558

EP - 2574

JO - Journal of Geophysical Research

JF - Journal of Geophysical Research

IS - 6

ER -

Observing and modeling the influence of layering on bubble trapping in polar firn

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