The atmospheric response to realistic reduced summer arctic sea ice anomalies

Uma S. Bhatt; Michael A. Alexander; Clara Deser; John E. Walsh; Jack S. Miller; Michael S. Timlin; James Scott; Robert A. Tomas

doi:10.1029/180GM08

The atmospheric response to realistic reduced summer arctic sea ice anomalies

Uma S. Bhatt
, Michael A. Alexander
, Clara Deser
, John E. Walsh
, Jack S. Miller
, Michael S. Timlin
, James Scott
, Robert A. Tomas

Climate Analysis

University of Alaska Fairbanks
National Oceanic and Atmospheric Administration
University of Illinois at Urbana-Champaign
National Center for Atmospheric Research

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

24 Scopus citations

Abstract

The impact of reduced Arctic summer sea ice on the atmosphere is investigated by forcing an atmospheric general circulation model, the Community Climate Model (CCM 3.6), with observed sea ice conditions during 1995, a low-ice year. The 51 experiments, which spanned April to October of 1995, were initiated with different states from a control simulation. The 55-year control was integrated using a repeating climatological seasonal cycle of sea ice. The response was obtained from the mean difference between the experiment and control simulations. The strongest response was found during the month of August where the Arctic displays a weak local thermal response, with warmer surface air temperatures and lower sea level pressure (SLP). However, there is a significant remote response over the North Pacific characterized by an equivalent barotropic (anomalies are collocated with height and increase in magnitude) structure, with anomalous high SLP collocated with a ridge in the upper troposphere. The ice anomalies force an increase (decrease) in precipitation north of (along) the North Pacific storm track. A linear baroclinic model forced with the transient eddy vorticity fluxes, transient eddy heat fluxes, and diabatic heating separately demonstrated that transient eddy vorticity fluxes are key to maintaining the anomalous high over the North Pacific. The model’s sensitivity to separately imposed ice anomalies in the Kara, Laptev–East Siberian, or Beaufort seas includes SLP, geopotential height, and precipitation changes that are similar to but weaker than the response to the full sea ice anomaly.

Original language	English
Title of host publication	Arctic Sea Ice Decline
Subtitle of host publication	Observations, Projections, Mechanisms, and Implications, 2008
Editors	Eric T. DeWeaver, Cecilia M. Bitz, L.-Bruno Tremblay
Publisher	Blackwell Publishing Ltd
Pages	91-110
Number of pages	20
ISBN (Electronic)	9781118666470
ISBN (Print)	9780875904450
DOIs	https://doi.org/10.1029/180GM08
State	Published - 2008

Publication series

Name	Geophysical Monograph Series
Volume	180
ISSN (Print)	0065-8448
ISSN (Electronic)	2328-8779

Keywords

Arctic regions-Climate
Climatic changes-Environmental aspects-Arctic Regions
Environmental impact analysis-Arctic regions
Sea ice-Arctic regions

Access to Document

10.1029/180GM08

Cite this

Bhatt, U. S., Alexander, M. A., Deser, C., Walsh, J. E., Miller, J. S., Timlin, M. S., Scott, J., & Tomas, R. A. (2008). The atmospheric response to realistic reduced summer arctic sea ice anomalies. In E. T. DeWeaver, C. M. Bitz, & L. .-B. Tremblay (Eds.), Arctic Sea Ice Decline: Observations, Projections, Mechanisms, and Implications, 2008 (pp. 91-110). (Geophysical Monograph Series; Vol. 180). Blackwell Publishing Ltd. https://doi.org/10.1029/180GM08

@inproceedings{9fef83c1baab4a4c80e50a85895c9622,

title = "The atmospheric response to realistic reduced summer arctic sea ice anomalies",

abstract = "The impact of reduced Arctic summer sea ice on the atmosphere is investigated by forcing an atmospheric general circulation model, the Community Climate Model (CCM 3.6), with observed sea ice conditions during 1995, a low-ice year. The 51 experiments, which spanned April to October of 1995, were initiated with different states from a control simulation. The 55-year control was integrated using a repeating climatological seasonal cycle of sea ice. The response was obtained from the mean difference between the experiment and control simulations. The strongest response was found during the month of August where the Arctic displays a weak local thermal response, with warmer surface air temperatures and lower sea level pressure (SLP). However, there is a significant remote response over the North Pacific characterized by an equivalent barotropic (anomalies are collocated with height and increase in magnitude) structure, with anomalous high SLP collocated with a ridge in the upper troposphere. The ice anomalies force an increase (decrease) in precipitation north of (along) the North Pacific storm track. A linear baroclinic model forced with the transient eddy vorticity fluxes, transient eddy heat fluxes, and diabatic heating separately demonstrated that transient eddy vorticity fluxes are key to maintaining the anomalous high over the North Pacific. The model{\textquoteright}s sensitivity to separately imposed ice anomalies in the Kara, Laptev–East Siberian, or Beaufort seas includes SLP, geopotential height, and precipitation changes that are similar to but weaker than the response to the full sea ice anomaly.",

keywords = "Arctic regions-Climate, Climatic changes-Environmental aspects-Arctic Regions, Environmental impact analysis-Arctic regions, Sea ice-Arctic regions",

author = "Bhatt, \{Uma S.\} and Alexander, \{Michael A.\} and Clara Deser and Walsh, \{John E.\} and Miller, \{Jack S.\} and Timlin, \{Michael S.\} and James Scott and Tomas, \{Robert A.\}",

note = "Publisher Copyright: {\textcopyright} 2008 by the American Geophysical Union.",

year = "2008",

doi = "10.1029/180GM08",

language = "English",

isbn = "9780875904450",

series = "Geophysical Monograph Series",

publisher = "Blackwell Publishing Ltd",

pages = "91--110",

editor = "DeWeaver, \{Eric T.\} and Bitz, \{Cecilia M.\} and L.-Bruno Tremblay",

booktitle = "Arctic Sea Ice Decline",

}

Bhatt, US, Alexander, MA, Deser, C, Walsh, JE, Miller, JS, Timlin, MS, Scott, J & Tomas, RA 2008, The atmospheric response to realistic reduced summer arctic sea ice anomalies. in ET DeWeaver, CM Bitz & L-B Tremblay (eds), Arctic Sea Ice Decline: Observations, Projections, Mechanisms, and Implications, 2008. Geophysical Monograph Series, vol. 180, Blackwell Publishing Ltd, pp. 91-110. https://doi.org/10.1029/180GM08

The atmospheric response to realistic reduced summer arctic sea ice anomalies. / Bhatt, Uma S.; Alexander, Michael A.; Deser, Clara et al.
Arctic Sea Ice Decline: Observations, Projections, Mechanisms, and Implications, 2008. ed. / Eric T. DeWeaver; Cecilia M. Bitz; L.-Bruno Tremblay. Blackwell Publishing Ltd, 2008. p. 91-110 (Geophysical Monograph Series; Vol. 180).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - The atmospheric response to realistic reduced summer arctic sea ice anomalies

AU - Bhatt, Uma S.

AU - Alexander, Michael A.

AU - Deser, Clara

AU - Walsh, John E.

AU - Miller, Jack S.

AU - Timlin, Michael S.

AU - Scott, James

AU - Tomas, Robert A.

PY - 2008

Y1 - 2008

N2 - The impact of reduced Arctic summer sea ice on the atmosphere is investigated by forcing an atmospheric general circulation model, the Community Climate Model (CCM 3.6), with observed sea ice conditions during 1995, a low-ice year. The 51 experiments, which spanned April to October of 1995, were initiated with different states from a control simulation. The 55-year control was integrated using a repeating climatological seasonal cycle of sea ice. The response was obtained from the mean difference between the experiment and control simulations. The strongest response was found during the month of August where the Arctic displays a weak local thermal response, with warmer surface air temperatures and lower sea level pressure (SLP). However, there is a significant remote response over the North Pacific characterized by an equivalent barotropic (anomalies are collocated with height and increase in magnitude) structure, with anomalous high SLP collocated with a ridge in the upper troposphere. The ice anomalies force an increase (decrease) in precipitation north of (along) the North Pacific storm track. A linear baroclinic model forced with the transient eddy vorticity fluxes, transient eddy heat fluxes, and diabatic heating separately demonstrated that transient eddy vorticity fluxes are key to maintaining the anomalous high over the North Pacific. The model’s sensitivity to separately imposed ice anomalies in the Kara, Laptev–East Siberian, or Beaufort seas includes SLP, geopotential height, and precipitation changes that are similar to but weaker than the response to the full sea ice anomaly.

AB - The impact of reduced Arctic summer sea ice on the atmosphere is investigated by forcing an atmospheric general circulation model, the Community Climate Model (CCM 3.6), with observed sea ice conditions during 1995, a low-ice year. The 51 experiments, which spanned April to October of 1995, were initiated with different states from a control simulation. The 55-year control was integrated using a repeating climatological seasonal cycle of sea ice. The response was obtained from the mean difference between the experiment and control simulations. The strongest response was found during the month of August where the Arctic displays a weak local thermal response, with warmer surface air temperatures and lower sea level pressure (SLP). However, there is a significant remote response over the North Pacific characterized by an equivalent barotropic (anomalies are collocated with height and increase in magnitude) structure, with anomalous high SLP collocated with a ridge in the upper troposphere. The ice anomalies force an increase (decrease) in precipitation north of (along) the North Pacific storm track. A linear baroclinic model forced with the transient eddy vorticity fluxes, transient eddy heat fluxes, and diabatic heating separately demonstrated that transient eddy vorticity fluxes are key to maintaining the anomalous high over the North Pacific. The model’s sensitivity to separately imposed ice anomalies in the Kara, Laptev–East Siberian, or Beaufort seas includes SLP, geopotential height, and precipitation changes that are similar to but weaker than the response to the full sea ice anomaly.

KW - Arctic regions-Climate

KW - Climatic changes-Environmental aspects-Arctic Regions

KW - Environmental impact analysis-Arctic regions

KW - Sea ice-Arctic regions

UR - https://www.scopus.com/pages/publications/84951029883

U2 - 10.1029/180GM08

DO - 10.1029/180GM08

M3 - Conference contribution

AN - SCOPUS:84951029883

SN - 9780875904450

T3 - Geophysical Monograph Series

SP - 91

EP - 110

BT - Arctic Sea Ice Decline

A2 - DeWeaver, Eric T.

A2 - Bitz, Cecilia M.

A2 - Tremblay, L.-Bruno

PB - Blackwell Publishing Ltd

ER -

Bhatt US, Alexander MA, Deser C, Walsh JE, Miller JS, Timlin MS et al. The atmospheric response to realistic reduced summer arctic sea ice anomalies. In DeWeaver ET, Bitz CM, Tremblay LB, editors, Arctic Sea Ice Decline: Observations, Projections, Mechanisms, and Implications, 2008. Blackwell Publishing Ltd. 2008. p. 91-110. (Geophysical Monograph Series). doi: 10.1029/180GM08

The atmospheric response to realistic reduced summer arctic sea ice anomalies

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