Southern Hemisphere atmospheric history of carbon monoxide over the late Holocene reconstructed from multiple Antarctic ice archives
Carbon monoxide (CO) is a naturally occurring atmospheric trace gas, a regulated pollutant, and one of the main components determining the oxidative capacity of the atmosphere. Evaluating climate-chemistry models under different conditions than today and constraining past CO sources requires a relia...
| Published in: | Climate of the Past |
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| Main Authors: | , , , , , , , , , , , , , , , , , , |
| Format: | Article in Journal/Newspaper |
| Language: | unknown |
| Published: |
Copernicus Publications
2023
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| Subjects: | |
| Online Access: | https://epic.awi.de/id/eprint/59062/ https://epic.awi.de/id/eprint/59062/1/cp-19-2287-2023.pdf https://doi.org/10.5194/cp-19-2287-2023 https://hdl.handle.net/10013/epic.815caea2-bd56-4ae7-bbaa-a427c8907530 |
| Summary: | Carbon monoxide (CO) is a naturally occurring atmospheric trace gas, a regulated pollutant, and one of the main components determining the oxidative capacity of the atmosphere. Evaluating climate-chemistry models under different conditions than today and constraining past CO sources requires a reliable record of atmospheric CO mixing ratios ([CO]) that includes data since preindustrial times. Here, we report the first continuous record of atmospheric [CO] for Southern Hemisphere (SH) high latitudes over the past 3 millennia. Our continuous record is a composite of three high-resolution Antarctic ice core gas records and firn air measurements from seven Antarctic locations. The ice core gas [CO] records were measured by continuous flow analysis (CFA), using an optical feedback cavity-enhanced absorption spectrometer (OF-CEAS), achieving excellent external precision (2.8-8.8gppb; 2σ) and consistently low blanks (ranging from 4.1±1.2 to 7.4±1.4gppb), thus enabling paleo-Atmospheric interpretations. Six new firn air [CO] Antarctic datasets collected between 1993 and 2016gCE at the DE08-2, DSSW19K, DSSW20K, South Pole, Aurora Basin North (ABN), and Lock-In sites (and one previously published firn CO dataset at Berkner) were used to reconstruct the atmospheric history of CO from g1/41897gCE, using inverse modeling that incorporates the influence of gas transport in firn. Excellent consistency was observed between the youngest ice core gas [CO] and the [CO] from the base of the firn and between the recent firn [CO] and atmospheric [CO] measurements at Mawson station (eastern Antarctica), yielding a consistent and contiguous record of CO across these different archives. Our Antarctic [CO] record is relatively stable from-835 to 1500gCE, with mixing ratios within a 30-45gppb range (2σ). There is a g1/45gppb decrease in [CO] to a minimum at around 1700gCE during the Little Ice Age. CO mixing ratios then increase over time to reach a maximum of g1/454gppb by g1/41985gCE. Most of the industrial period [CO] growth occurred ... |
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