Interannual global carbon cycle variations  linked to atmospheric circulation variability

Li, Na; Sippel, Sebastian; Winkler, Alexander J.; Mahecha, Miguel D.; Reichstein, Markus; Bastos, Ana

doi:10.5194/esd-13-1505-2022

Articles | Volume 13, issue 4

https://doi.org/10.5194/esd-13-1505-2022

© Author(s) 2022. This work is distributed under
the Creative Commons Attribution 4.0 License.

https://doi.org/10.5194/esd-13-1505-2022

© Author(s) 2022. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 13, issue 4

Research article

|

07 Nov 2022

Research article |

| 07 Nov 2022

Interannual global carbon cycle variations linked to atmospheric circulation variability

Na Li, Sebastian Sippel, Alexander J. Winkler, Miguel D. Mahecha, Markus Reichstein, and Ana Bastos

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Oct 2022	27	11	2	40
Nov 2022	390	48	3	441
Dec 2022	175	15	1	191
Jan 2023	118	13	1	132
Feb 2023	42	14	0	56
Mar 2023	44	23	2	69
Apr 2023	37	15	0	52
May 2023	19	14	0	33
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Jan 2024	115	6	1	122
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Apr 2024	55	6	11	72
May 2024	53	9	3	65
Jun 2024	143	11	2	156
Jul 2024	411	8	6	425
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Feb 2025	48	3	1	52
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Apr 2025	50	12	1	63
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Jun 2025	78	16	3	97
Jul 2025	53	14	4	71
Aug 2025	54	12	0	66
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Cumulative views and downloads (calculated since 04 Apr 2022)

Month	HTML	PDF	XML	Total
Apr 2022	318	108	5	431
May 2022	85	18	0	103
Jun 2022	64	17	2	83
Jul 2022	22	9	0	31
Aug 2022	20	8	0	28
Sep 2022	19	10	0	29
Oct 2022	27	11	2	40
Nov 2022	390	48	3	441
Dec 2022	175	15	1	191
Jan 2023	118	13	1	132
Feb 2023	42	14	0	56
Mar 2023	44	23	2	69
Apr 2023	37	15	0	52
May 2023	19	14	0	33
Jun 2023	14	9	2	25
Jul 2023	23	12	0	35
Aug 2023	25	12	1	38
Sep 2023	23	10	2	35
Oct 2023	37	9	1	47
Nov 2023	21	4	0	25
Dec 2023	32	8	1	41
Jan 2024	115	6	1	122
Feb 2024	22	8	2	32
Mar 2024	25	22	2	49
Apr 2024	55	6	11	72
May 2024	53	9	3	65
Jun 2024	143	11	2	156
Jul 2024	411	8	6	425
Aug 2024	48	3	6	57
Sep 2024	26	9	3	38
Oct 2024	38	10	1	49
Nov 2024	23	5	3	31
Dec 2024	21	7	1	29
Jan 2025	41	4	2	47
Feb 2025	48	3	1	52
Mar 2025	28	14	1	43
Apr 2025	50	12	1	63
May 2025	38	6	0	44
Jun 2025	78	16	3	97
Jul 2025	53	14	4	71
Aug 2025	54	12	0	66
Sep 2025	191	15	1	207
Oct 2025	44	16	2	62
Nov 2025	13	5	0	18

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Short summary

Quantifying the imprint of large-scale atmospheric circulation dynamics and associated carbon cycle responses is key to improving our understanding of carbon cycle dynamics. Using a statistical model that relies on spatiotemporal sea level pressure as a proxy for large-scale atmospheric circulation, we quantify the fraction of interannual variability in atmospheric CO₂ growth rate and the land CO₂ sink that are driven by atmospheric circulation variability.


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