An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter

We present the implementation and results of a model tuning and ensemble forecasting experiment using an ensemble Kalman filter for the simultaneous estimation of 12 parameters in a low resolution coupled atmosphere-ocean Earth System Model by tuning it to realistic data sets consisting of Levitus o...

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Published in:Climate Dynamics
Main Authors: Hargreaves, J.C., Annan, J.D., Edwards, N.R., Marsh, R.
Format: Article in Journal/Newspaper
Language:unknown
Published: 2004
Subjects:
Online Access:https://eprints.soton.ac.uk/24075/
http://www.metapress.com/media/7ped06ptqn0uwmfynwul/contributions/0/j/t/a/0jtavcecm5cl3ulx_html/fulltext.html
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spelling ftsouthampton:oai:eprints.soton.ac.uk:24075 2023-07-30T04:05:38+02:00 An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter Hargreaves, J.C. Annan, J.D. Edwards, N.R. Marsh, R. 2004 https://eprints.soton.ac.uk/24075/ http://www.metapress.com/media/7ped06ptqn0uwmfynwul/contributions/0/j/t/a/0jtavcecm5cl3ulx_html/fulltext.html unknown Hargreaves, J.C., Annan, J.D., Edwards, N.R. and Marsh, R. (2004) An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter. Climate Dynamics, 23 (7-8), 745-760. (doi:10.1007/s00382-004-0471-4 <http://dx.doi.org/10.1007/s00382-004-0471-4>). Article PeerReviewed 2004 ftsouthampton https://doi.org/10.1007/s00382-004-0471-4 2023-07-09T20:39:01Z We present the implementation and results of a model tuning and ensemble forecasting experiment using an ensemble Kalman filter for the simultaneous estimation of 12 parameters in a low resolution coupled atmosphere-ocean Earth System Model by tuning it to realistic data sets consisting of Levitus ocean temperature/salinity climatology, and NCEP/NCAR atmospheric temperature/humidity reanalysis data. The resulting ensemble of tuned model states is validated by comparing various diagnostics, such as mass and heat transports, to observational estimates and other model results. We show that this ensemble has a very reasonable climatology, with the 3-D ocean in particular having comparable realism to much more expensive coupled numerical models, at least in respect of these averaged indicators. A simple global warming experiment is performed to investigate the response and predictability of the climate to a change in radiative forcing, due to 100 years of 1% per annum atmospheric CO2 increase. The equilibrium surface air temperature rise for this CO2 increase is 4.2±0.1°C, which is approached on a time scale of 1,000 years. The simple atmosphere in this version of the model is missing several factors which, if included, would substantially increase the uncertainty of this estimate. However, even within this ensemble, there is substantial regional variability due to the possibility of collapse of the North Atlantic thermohaline circulation (THC), which switches off in more than one third of the ensemble members. For these cases, the regional temperature is not only 3–5°C colder than in the warmed worlds where the THC remains switched on, but is also 1–2°C colder than the current climate. Our results, which illustrate how objective probabilistic projections of future climate change can be efficiently generated, indicate a substantial uncertainty in the long-term future of the THC, and therefore the regional climate of western Europe. However, this uncertainty is only apparent in long-term integrations, with the initial ... Article in Journal/Newspaper North Atlantic North atlantic Thermohaline circulation University of Southampton: e-Prints Soton Climate Dynamics 23 7-8 745 760
institution Open Polar
collection University of Southampton: e-Prints Soton
op_collection_id ftsouthampton
language unknown
description We present the implementation and results of a model tuning and ensemble forecasting experiment using an ensemble Kalman filter for the simultaneous estimation of 12 parameters in a low resolution coupled atmosphere-ocean Earth System Model by tuning it to realistic data sets consisting of Levitus ocean temperature/salinity climatology, and NCEP/NCAR atmospheric temperature/humidity reanalysis data. The resulting ensemble of tuned model states is validated by comparing various diagnostics, such as mass and heat transports, to observational estimates and other model results. We show that this ensemble has a very reasonable climatology, with the 3-D ocean in particular having comparable realism to much more expensive coupled numerical models, at least in respect of these averaged indicators. A simple global warming experiment is performed to investigate the response and predictability of the climate to a change in radiative forcing, due to 100 years of 1% per annum atmospheric CO2 increase. The equilibrium surface air temperature rise for this CO2 increase is 4.2±0.1°C, which is approached on a time scale of 1,000 years. The simple atmosphere in this version of the model is missing several factors which, if included, would substantially increase the uncertainty of this estimate. However, even within this ensemble, there is substantial regional variability due to the possibility of collapse of the North Atlantic thermohaline circulation (THC), which switches off in more than one third of the ensemble members. For these cases, the regional temperature is not only 3–5°C colder than in the warmed worlds where the THC remains switched on, but is also 1–2°C colder than the current climate. Our results, which illustrate how objective probabilistic projections of future climate change can be efficiently generated, indicate a substantial uncertainty in the long-term future of the THC, and therefore the regional climate of western Europe. However, this uncertainty is only apparent in long-term integrations, with the initial ...
format Article in Journal/Newspaper
author Hargreaves, J.C.
Annan, J.D.
Edwards, N.R.
Marsh, R.
spellingShingle Hargreaves, J.C.
Annan, J.D.
Edwards, N.R.
Marsh, R.
An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter
author_facet Hargreaves, J.C.
Annan, J.D.
Edwards, N.R.
Marsh, R.
author_sort Hargreaves, J.C.
title An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter
title_short An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter
title_full An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter
title_fullStr An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter
title_full_unstemmed An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter
title_sort efficient climate forecasting method using an intermediate complexity earth system model and the ensemble kalman filter
publishDate 2004
url https://eprints.soton.ac.uk/24075/
http://www.metapress.com/media/7ped06ptqn0uwmfynwul/contributions/0/j/t/a/0jtavcecm5cl3ulx_html/fulltext.html
genre North Atlantic
North atlantic Thermohaline circulation
genre_facet North Atlantic
North atlantic Thermohaline circulation
op_relation Hargreaves, J.C., Annan, J.D., Edwards, N.R. and Marsh, R. (2004) An efficient climate forecasting method using an intermediate complexity Earth system model and the ensemble Kalman Filter. Climate Dynamics, 23 (7-8), 745-760. (doi:10.1007/s00382-004-0471-4 <http://dx.doi.org/10.1007/s00382-004-0471-4>).
op_doi https://doi.org/10.1007/s00382-004-0471-4
container_title Climate Dynamics
container_volume 23
container_issue 7-8
container_start_page 745
op_container_end_page 760
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