Warm and moist air intrusions into the winter Arctic: a Lagrangian view on the near-surface energy budgets

You, Cheng; Tjernström, Michael; Devasthale, Abhay

doi:https://doi.org/10.5194/acp-22-8037-2022

Articles | Volume 22, issue 12

https://doi.org/10.5194/acp-22-8037-2022

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

https://doi.org/10.5194/acp-22-8037-2022

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

Articles | Volume 22, issue 12

Research article

|

21 Jun 2022

Research article |

| 21 Jun 2022

Warm and moist air intrusions into the winter Arctic: a Lagrangian view on the near-surface energy budgets

Cheng You, Michael Tjernström, and Abhay Devasthale

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Cumulative views and downloads (calculated since 17 Aug 2021)

Month	HTML	PDF	XML	Total
Aug 2021	44	15	4	63
Sep 2021	86	13	0	99
Oct 2021	115	17	4	136
Nov 2021	73	17	0	90
Dec 2021	20	10	1	31
Jan 2022	36	18	5	59
Feb 2022	28	17	3	48
Mar 2022	21	8	0	29
Apr 2022	42	11	0	53
May 2022	49	9	0	58
Jun 2022	298	50	5	353
Jul 2022	173	16	2	191
Aug 2022	80	16	0	96
Sep 2022	81	4	0	85
Oct 2022	69	9	0	78
Nov 2022	84	8	1	93
Dec 2022	73	17	1	91
Jan 2023	34	19	0	53
Feb 2023	31	14	0	45
Mar 2023	34	24	1	59
Apr 2023	24	14	2	40
May 2023	14	16	1	31
Jun 2023	25	9	2	36
Jul 2023	61	18	3	82
Aug 2023	23	27	2	52
Sep 2023	16	22	1	39
Oct 2023	26	9	2	37
Nov 2023	19	5	0	24
Dec 2023	27	10	0	37
Jan 2024	27	5	0	32
Feb 2024	19	24	3	46
Mar 2024	24	27	4	55
Apr 2024	23	18	2	43
May 2024	33	12	0	45
Jun 2024	49	23	18	90
Jul 2024	54	15	3	72
Aug 2024	30	19	3	52
Sep 2024	17	14	1	32
Oct 2024	17	20	0	37
Nov 2024	4	0	4

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Short summary

In winter when solar radiation is absent in the Arctic, the poleward transport of heat and moisture into the high Arctic becomes the main contribution of Arctic warming. Over completely frozen ocean sectors, total surface energy budget is dominated by net long-wave heat, while over the Barents Sea, with an open ocean to the south, total net surface energy budget is dominated by the surface turbulent heat.

Warm and moist air intrusions into the winter Arctic: a Lagrangian view on the near-surface energy budgets

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