A process-based evaluation of biases in extratropical stratosphere-troposphere coupling in subseasonal forecast systems

Chaim I. Garfinkel; Zachary D. Lawrence; Amy H. Butler; Etienne Dunn-Sigouin; Irina Statnaia; Alexey Y. Karpechko; Gerbrand Koren; Marta Abalos; Blanca Ayarzagüena; David Barriopedro; Natalia Calvo; Alvaro De La Cámara; Andrew Charlton-Perez; Judah Cohen; Daniela I.V. Domeisen; Javier García-Serrano; Neil P. Hindley; Martin Jucker; Hera Kim; Robert W. Lee; Simon H. Lee; Marisol Osman; Froila M. Palmeiro; Inna Polichtchouk; Jian Rao; Jadwiga H. Richter; Chen Schwartz; Seok Woo Son; Masakazu Taguchi; Nicholas L. Tyrrell; Corwin J. Wright; Rachel W.Y. Wu

doi:10.5194/wcd-6-171-2025

A process-based evaluation of biases in extratropical stratosphere-troposphere coupling in subseasonal forecast systems

Chaim I. Garfinkel^*, Zachary D. Lawrence, Amy H. Butler, Etienne Dunn-Sigouin, Irina Statnaia, Alexey Y. Karpechko, Gerbrand Koren, Marta Abalos, Blanca Ayarzagüena, David Barriopedro, Natalia Calvo, Alvaro De La Cámara, Andrew Charlton-Perez, Judah Cohen, Daniela I.V. Domeisen, Javier García-Serrano, Neil P. Hindley, Martin Jucker, Hera Kim, Robert W. LeeSimon H. Lee, Marisol Osman, Froila M. Palmeiro, Inna Polichtchouk, Jian Rao, Jadwiga H. Richter, Chen Schwartz, Seok Woo Son, Masakazu Taguchi, Nicholas L. Tyrrell, Corwin J. Wright, Rachel W.Y. Wu

^*Corresponding author for this work

Global Ecohydrology and Sustainability

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Two-way coupling between the stratosphere and troposphere is recognized as an important source of subseasonal-to-seasonal (S2S) predictability and can open windows of opportunity for improved forecasts. Model biases can, however, lead to a poor representation of such coupling processes; drifts in a model's circulation related to model biases, resolution, and parameterizations have the potential to feed back on the circulation and affect stratosphere-troposphere coupling. We introduce a set of diagnostics using readily available data that can be used to reveal these biases and then apply these diagnostics to 22 S2S forecast systems. In the Northern Hemisphere, nearly all S2S forecast systems underestimate the strength of the observed upward coupling from the troposphere to the stratosphere, downward coupling within the stratosphere, and the persistence of lower-stratospheric temperature anomalies. While downward coupling from the lower stratosphere to the near surface is well represented in the multi-model ensemble mean, there is substantial intermodel spread likely related to how well each model represents tropospheric stationary waves. In the Southern Hemisphere, the stratospheric vortex is oversensitive to upward-propagating wave flux in the forecast systems. Forecast systems generally overestimate the strength of downward coupling from the lower stratosphere to the troposphere, even as most underestimate the radiative persistence in the lower stratosphere. In both hemispheres, models with higher lids and a better representation of tropospheric quasi-stationary waves generally perform better at simulating these coupling processes.

Original language	English
Pages (from-to)	171-195
Number of pages	25
Journal	Weather and Climate Dynamics
Volume	6
Issue number	1
DOIs	https://doi.org/10.5194/wcd-6-171-2025
Publication status	Published - 7 Feb 2025

Bibliographical note

Publisher Copyright:
© 2025 Chaim I. Garfinkel et al.

Funding

Chaim I. Garfinkel and Jian Rao are supported by the ISF\u2013NSFC joint research program (Israel Science Foundation grant no. 3065/23 and National Natural Science Foundation of China grant no. 42361144843). Chaim I. Garfinkel and Judah Cohen are supported by the NSF\u2013BSF joint research program (National Science Foundation grant no. AGS-2140909 and United States\u2013Israel Binational Science Foundation grant no. 2021714). Irina Statnaia and Alexey Y. Karpechko are supported by the Research Council of Finland (grant no. 355792). The work of Marisol Osman is supported by UBACyT (project nos. 20020220100075BA, PIP 11220200102038CO, and PICT-2021-GRF-TI-00498). The work of Alvaro de la C\u00E1mara is funded by the Spanish Ministry of Science, Innovation and Universities (project no. PID2022-136316NB-I00). Marta Abalos, Blanca Ayarzag\u00FCena, and Natalia Calvo are supported by the Spanish Ministry of Science, Innovation and Universities through the RecO3very project (no. PID2021-124772OB-I00). Froila M. Palmeiro and Javier Garc\u00EDa-Serrano have been partially supported by the Spanish ATLANTE project (no. PID2019-110234RB-C21) and Ram\u00F3n y Cajal program (no. RYC-2016-21181), respectively. Neil P. Hindley and Corwin J. Wright are supported by the UK Natural Environment Research Council (NERC; grant no. NE/S00985X/1). Corwin J. Wright is also supported by a Royal Society University Research Fellowship (grant no. URF/R/221023). Seok-Woo Son and Hera Kim are supported by the National Research Foundation of Korea (NRF) grant funded by the Korean government (Ministry of Science and Information and Communication Technology, MSIT) (grant no. 2023R1A2C3005607). The work of Rachel W.-Y. Wu is funded through ETH (grant no. ETH-05 19-1). Daniela I. V. Domeisen is supported by the Swiss National Science Foundation (project no. PP00P2_198896). This material is based upon work supported by the U.S. Department of Energy Office of Science Biological and Environmental Research (BER) program Regional and Global Model Analysis (RGMA) component of the Earth and Environment Systems Modeling program (award no. DE-SC0022070) and National Science Foundation (NSF; grant no. IA 1947282). This work was also supported by the National Center for Atmospheric Research (NCAR), which is a major facility sponsored by the NSF (cooperative agreement no. 1852977). Zachary D. Lawrence was partially supported by NOAA (award no. NA20NWS4680051). This work uses S2S project data. S2S is a joint initiative of the World Weather Research Programme (WWRP) and the World Climate Research Programme (WCRP). This work was initiated by the Stratospheric Network for the Assessment of Predictability (SNAP), a joint program of APARC (WCRP) and the S2S project (WWRP-WCRP). Chaim I. Garfinkel and Jian Rao are supported by the ISF-NSFC joint research program (Israel Science Foundation grant no. 3065/23 and National Natural Science Foundation of China grant no. 42361144843). Chaim I. Garfinkel and Judah Cohen are supported by the NSF-BSF joint research program (National Science Foundation grant no. AGS-2140909 and United States-Israel Binational Science Foundation grant no. 2021714). Irina Statnaia and Alexey Y. Karpechko are supported by the Research Council of Finland (grant no. 355792). The work of Marisol Osman is supported by UBACyT (project nos. 20020220100075BA, PIP 11220200102038CO, and PICT- 2021-GRF-TI-00498). The work of Alvaro de la C mara is funded by the Spanish Ministry of Science, Innovation and Universities (project no. PID2022-136316NB-I00). Marta Abalos, Blanca Ayarzag ena, and Natalia Calvo are supported by the Spanish Ministry of Science, Innovation and Universities through the RecO3very project (no. PID2021-124772OB-I00). Froila M. Palmeiro and Javier Garc a-Serrano have been partially supported by the Spanish ATLANTE project (no. PID2019-110234RB-C21) and Ram n y Cajal program (no. RYC-2016-21181), respectively. Neil P. Hindley and Corwin J. Wright are supported by the UK Natural Environment Research Council (NERC; grant no. NE/S00985X/1). Corwin J. Wright is also supported by a Royal Society University Research Fellowship (grant no. URF/R/221023). Seok-Woo Son and Hera Kim are supported by the National Research Foundation of Korea (NRF) grant funded by the Korean gov ernment (Ministry of Science and Information and Communication Technology, MSIT) (grant no. 2023R1A2C3005607). The work of Rachel W.-Y. Wu is funded through ETH (grant no. ETH-05 19-1). Daniela I. V. Domeisen is supported by the Swiss National Science Foundation (project no. PP00P2_198896). This material is based upon work supported by the U.S. Department of Energy Office of Science Biological and Environmental Research (BER) program Regional and Global Model Analysis (RGMA) component of the Earth and Environment Systems Modeling program (award no. DE-SC0022070) and National Science Foundation (NSF; grant no. IA 1947282). This work was also supported by the National Center for Atmospheric Research (NCAR), which is a major facility sponsored by the NSF (cooperative agreement no. 1852977). Zachary D. Lawrence was partially supported by NOAA (award no. NA20NWS4680051).

Funders	Funder number
Ministry of Science and ICT, South Korea
National Research Foundation of Korea
Earth and Environment Systems Modeling program
Korean gov ernment
NSF-BSF
APARC
ISF-NSFC
National Science Foundation	IA 1947282, AGS-2140909
National Oceanic and Atmospheric Administration	NA20NWS4680051
National Natural Science Foundation of China	42361144843
Biological and Environmental Research	DE-SC0022070
MSIT	2023R1A2C3005607
Research Council of Finland	355792
National Center for Atmospheric Research	1852977
Natural Environment Research Council	NE/S00985X/1
United States-Israel Binational Science Foundation	2021714
Royal Society	URF/R/221023
Israel Science Foundation	3065/23
Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung	PP00P2_198896
Secretaría de Ciencia y Técnica, Universidad de Buenos Aires	PICT-2021-GRF-TI-00498, 20020220100075BA, PIP 11220200102038CO
Eidgenössische Technische Hochschule Zürich	ETH-05 19-1
ATLANTE	RYC-2016-21181, PID2019-110234RB-C21
Ministerio de Ciencia, Innovación y Universidades	PID2022-136316NB-I00, PID2021-124772OB-I00

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Garfinkel, C. I., Lawrence, Z. D., Butler, A. H., Dunn-Sigouin, E., Statnaia, I., Karpechko, A. Y., Koren, G., Abalos, M., Ayarzagüena, B., Barriopedro, D., Calvo, N., De La Cámara, A., Charlton-Perez, A., Cohen, J., Domeisen, D. I. V., García-Serrano, J., Hindley, N. P., Jucker, M., Kim, H., ... Wu, R. W. Y. (2025). A process-based evaluation of biases in extratropical stratosphere-troposphere coupling in subseasonal forecast systems. Weather and Climate Dynamics, 6(1), 171-195. https://doi.org/10.5194/wcd-6-171-2025

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title = "A process-based evaluation of biases in extratropical stratosphere-troposphere coupling in subseasonal forecast systems",

abstract = "Two-way coupling between the stratosphere and troposphere is recognized as an important source of subseasonal-to-seasonal (S2S) predictability and can open windows of opportunity for improved forecasts. Model biases can, however, lead to a poor representation of such coupling processes; drifts in a model's circulation related to model biases, resolution, and parameterizations have the potential to feed back on the circulation and affect stratosphere-troposphere coupling. We introduce a set of diagnostics using readily available data that can be used to reveal these biases and then apply these diagnostics to 22 S2S forecast systems. In the Northern Hemisphere, nearly all S2S forecast systems underestimate the strength of the observed upward coupling from the troposphere to the stratosphere, downward coupling within the stratosphere, and the persistence of lower-stratospheric temperature anomalies. While downward coupling from the lower stratosphere to the near surface is well represented in the multi-model ensemble mean, there is substantial intermodel spread likely related to how well each model represents tropospheric stationary waves. In the Southern Hemisphere, the stratospheric vortex is oversensitive to upward-propagating wave flux in the forecast systems. Forecast systems generally overestimate the strength of downward coupling from the lower stratosphere to the troposphere, even as most underestimate the radiative persistence in the lower stratosphere. In both hemispheres, models with higher lids and a better representation of tropospheric quasi-stationary waves generally perform better at simulating these coupling processes.",

author = "Garfinkel, \{Chaim I.\} and Lawrence, \{Zachary D.\} and Butler, \{Amy H.\} and Etienne Dunn-Sigouin and Irina Statnaia and Karpechko, \{Alexey Y.\} and Gerbrand Koren and Marta Abalos and Blanca Ayarzag{\"u}ena and David Barriopedro and Natalia Calvo and \{De La C{\'a}mara\}, Alvaro and Andrew Charlton-Perez and Judah Cohen and Domeisen, \{Daniela I.V.\} and Javier Garc{\'i}a-Serrano and Hindley, \{Neil P.\} and Martin Jucker and Hera Kim and Lee, \{Robert W.\} and Lee, \{Simon H.\} and Marisol Osman and Palmeiro, \{Froila M.\} and Inna Polichtchouk and Jian Rao and Richter, \{Jadwiga H.\} and Chen Schwartz and Son, \{Seok Woo\} and Masakazu Taguchi and Tyrrell, \{Nicholas L.\} and Wright, \{Corwin J.\} and Wu, \{Rachel W.Y.\}",

note = "Publisher Copyright: {\textcopyright} 2025 Chaim I. Garfinkel et al.",

year = "2025",

month = feb,

day = "7",

doi = "10.5194/wcd-6-171-2025",

language = "English",

volume = "6",

pages = "171--195",

journal = "Weather and Climate Dynamics",

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publisher = "Copernicus Gesellschaft mbH",

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Garfinkel, CI, Lawrence, ZD, Butler, AH, Dunn-Sigouin, E, Statnaia, I, Karpechko, AY, Koren, G, Abalos, M, Ayarzagüena, B, Barriopedro, D, Calvo, N, De La Cámara, A, Charlton-Perez, A, Cohen, J, Domeisen, DIV, García-Serrano, J, Hindley, NP, Jucker, M, Kim, H, Lee, RW, Lee, SH, Osman, M, Palmeiro, FM, Polichtchouk, I, Rao, J, Richter, JH, Schwartz, C, Son, SW, Taguchi, M, Tyrrell, NL, Wright, CJ & Wu, RWY 2025, 'A process-based evaluation of biases in extratropical stratosphere-troposphere coupling in subseasonal forecast systems', Weather and Climate Dynamics, vol. 6, no. 1, pp. 171-195. https://doi.org/10.5194/wcd-6-171-2025

TY - JOUR

T1 - A process-based evaluation of biases in extratropical stratosphere-troposphere coupling in subseasonal forecast systems

AU - Garfinkel, Chaim I.

AU - Lawrence, Zachary D.

AU - Butler, Amy H.

AU - Dunn-Sigouin, Etienne

AU - Statnaia, Irina

AU - Karpechko, Alexey Y.

AU - Koren, Gerbrand

AU - Abalos, Marta

AU - Ayarzagüena, Blanca

AU - Barriopedro, David

AU - Calvo, Natalia

AU - De La Cámara, Alvaro

AU - Charlton-Perez, Andrew

AU - Cohen, Judah

AU - Domeisen, Daniela I.V.

AU - García-Serrano, Javier

AU - Hindley, Neil P.

AU - Jucker, Martin

AU - Kim, Hera

AU - Lee, Robert W.

AU - Lee, Simon H.

AU - Osman, Marisol

AU - Palmeiro, Froila M.

AU - Polichtchouk, Inna

AU - Rao, Jian

AU - Richter, Jadwiga H.

AU - Schwartz, Chen

AU - Son, Seok Woo

AU - Taguchi, Masakazu

AU - Tyrrell, Nicholas L.

AU - Wright, Corwin J.

AU - Wu, Rachel W.Y.

PY - 2025/2/7

Y1 - 2025/2/7

N2 - Two-way coupling between the stratosphere and troposphere is recognized as an important source of subseasonal-to-seasonal (S2S) predictability and can open windows of opportunity for improved forecasts. Model biases can, however, lead to a poor representation of such coupling processes; drifts in a model's circulation related to model biases, resolution, and parameterizations have the potential to feed back on the circulation and affect stratosphere-troposphere coupling. We introduce a set of diagnostics using readily available data that can be used to reveal these biases and then apply these diagnostics to 22 S2S forecast systems. In the Northern Hemisphere, nearly all S2S forecast systems underestimate the strength of the observed upward coupling from the troposphere to the stratosphere, downward coupling within the stratosphere, and the persistence of lower-stratospheric temperature anomalies. While downward coupling from the lower stratosphere to the near surface is well represented in the multi-model ensemble mean, there is substantial intermodel spread likely related to how well each model represents tropospheric stationary waves. In the Southern Hemisphere, the stratospheric vortex is oversensitive to upward-propagating wave flux in the forecast systems. Forecast systems generally overestimate the strength of downward coupling from the lower stratosphere to the troposphere, even as most underestimate the radiative persistence in the lower stratosphere. In both hemispheres, models with higher lids and a better representation of tropospheric quasi-stationary waves generally perform better at simulating these coupling processes.

AB - Two-way coupling between the stratosphere and troposphere is recognized as an important source of subseasonal-to-seasonal (S2S) predictability and can open windows of opportunity for improved forecasts. Model biases can, however, lead to a poor representation of such coupling processes; drifts in a model's circulation related to model biases, resolution, and parameterizations have the potential to feed back on the circulation and affect stratosphere-troposphere coupling. We introduce a set of diagnostics using readily available data that can be used to reveal these biases and then apply these diagnostics to 22 S2S forecast systems. In the Northern Hemisphere, nearly all S2S forecast systems underestimate the strength of the observed upward coupling from the troposphere to the stratosphere, downward coupling within the stratosphere, and the persistence of lower-stratospheric temperature anomalies. While downward coupling from the lower stratosphere to the near surface is well represented in the multi-model ensemble mean, there is substantial intermodel spread likely related to how well each model represents tropospheric stationary waves. In the Southern Hemisphere, the stratospheric vortex is oversensitive to upward-propagating wave flux in the forecast systems. Forecast systems generally overestimate the strength of downward coupling from the lower stratosphere to the troposphere, even as most underestimate the radiative persistence in the lower stratosphere. In both hemispheres, models with higher lids and a better representation of tropospheric quasi-stationary waves generally perform better at simulating these coupling processes.

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U2 - 10.5194/wcd-6-171-2025

DO - 10.5194/wcd-6-171-2025

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SN - 2698-4016

VL - 6

SP - 171

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JO - Weather and Climate Dynamics

JF - Weather and Climate Dynamics

IS - 1

ER -

A process-based evaluation of biases in extratropical stratosphere-troposphere coupling in subseasonal forecast systems

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