The Challenge of Simulating the Warmth of the Mid-Miocene Climatic Optimun in CESM1

The mid-Miocene climatic optimum (MMCO) is an intriguing climatic period due to its above-modern temperatures in mid-to-high latitudes in the presence of close-to-modern CO2 concentrations. We use the recently released Community Earth System Model (CESM1.0) with a slab ocean to simulate this warm pe...

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Main Authors: Goldner, A., Herold, N., Huber, Matthew
Format: Text
Language:unknown
Published: Purdue University 2014
Subjects:
Antarctic
Pacific
Antarc*
Ice Sheet
Online Access:https://docs.lib.purdue.edu/easpubs/185
https://docs.lib.purdue.edu/context/easpubs/article/1173/viewcontent/Mid_myocene_climaticOptimun_2014.pdf
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spelling ftpurdueuniv:oai:docs.lib.purdue.edu:easpubs-1173 2023-07-02T03:30:35+02:00 The Challenge of Simulating the Warmth of the Mid-Miocene Climatic Optimun in CESM1 Goldner, A. Herold, N. Huber, Matthew 2014-03-13T07:00:00Z application/pdf https://docs.lib.purdue.edu/easpubs/185 https://docs.lib.purdue.edu/context/easpubs/article/1173/viewcontent/Mid_myocene_climaticOptimun_2014.pdf unknown Purdue University https://docs.lib.purdue.edu/easpubs/185 https://docs.lib.purdue.edu/context/easpubs/article/1173/viewcontent/Mid_myocene_climaticOptimun_2014.pdf Department of Earth, Atmospheric, and Planetary Sciences Faculty Publications text 2014 ftpurdueuniv 2023-06-12T21:03:50Z The mid-Miocene climatic optimum (MMCO) is an intriguing climatic period due to its above-modern temperatures in mid-to-high latitudes in the presence of close-to-modern CO2 concentrations. We use the recently released Community Earth System Model (CESM1.0) with a slab ocean to simulate this warm period, incorporating recent Miocene CO2 reconstructions of 400 ppm (parts per million). We simulate a global mean annual temperature (MAT) of 18 °C, ~4 °C above the preindustrial value, but 4 °C colder than the global Miocene MAT we calculate from climate proxies. Sensitivity tests reveal that the inclusion of a reduced Antarctic ice sheet, an equatorial Pacific temperature gradient characteristic of a permanent El Niño, increased CO2 to 560 ppm, and variations in obliquity only marginally improve model–data agreement. All MMCO simulations have an Equator to pole temperature gradient that is at least ~10 °C larger than that reconstructed from proxies. The MMCO simulation most comparable to the proxy records requires a CO2 concentration of 800 ppm. Our results illustrate that MMCO warmth is not reproducible using the CESM1.0 forced with CO2 concentrations reconstructed for the Miocene or including various proposed Earth system feedbacks; the remaining discrepancy in the MAT is comparable to that introduced by a CO2 doubling. The model's tendency to underestimate proxy derived global MAT and overestimate the Equator to pole temperature gradient suggests a major climate problem in the MMCO akin to those in the Eocene. Our results imply that this latest model, as with previous generations of climate models, is either not sensitive enough or additional forcings remain missing that explain half of the anomalous warmth and pronounced polar amplification of the MMCO. Text Antarc* Antarctic Ice Sheet Purdue University: e-Pubs Antarctic Pacific
institution Open Polar
collection Purdue University: e-Pubs
op_collection_id ftpurdueuniv
language unknown
description The mid-Miocene climatic optimum (MMCO) is an intriguing climatic period due to its above-modern temperatures in mid-to-high latitudes in the presence of close-to-modern CO2 concentrations. We use the recently released Community Earth System Model (CESM1.0) with a slab ocean to simulate this warm period, incorporating recent Miocene CO2 reconstructions of 400 ppm (parts per million). We simulate a global mean annual temperature (MAT) of 18 °C, ~4 °C above the preindustrial value, but 4 °C colder than the global Miocene MAT we calculate from climate proxies. Sensitivity tests reveal that the inclusion of a reduced Antarctic ice sheet, an equatorial Pacific temperature gradient characteristic of a permanent El Niño, increased CO2 to 560 ppm, and variations in obliquity only marginally improve model–data agreement. All MMCO simulations have an Equator to pole temperature gradient that is at least ~10 °C larger than that reconstructed from proxies. The MMCO simulation most comparable to the proxy records requires a CO2 concentration of 800 ppm. Our results illustrate that MMCO warmth is not reproducible using the CESM1.0 forced with CO2 concentrations reconstructed for the Miocene or including various proposed Earth system feedbacks; the remaining discrepancy in the MAT is comparable to that introduced by a CO2 doubling. The model's tendency to underestimate proxy derived global MAT and overestimate the Equator to pole temperature gradient suggests a major climate problem in the MMCO akin to those in the Eocene. Our results imply that this latest model, as with previous generations of climate models, is either not sensitive enough or additional forcings remain missing that explain half of the anomalous warmth and pronounced polar amplification of the MMCO.
format Text
author Goldner, A.
Herold, N.
Huber, Matthew
spellingShingle Goldner, A.
Herold, N.
Huber, Matthew
The Challenge of Simulating the Warmth of the Mid-Miocene Climatic Optimun in CESM1
author_facet Goldner, A.
Herold, N.
Huber, Matthew
author_sort Goldner, A.
title The Challenge of Simulating the Warmth of the Mid-Miocene Climatic Optimun in CESM1
title_short The Challenge of Simulating the Warmth of the Mid-Miocene Climatic Optimun in CESM1
title_full The Challenge of Simulating the Warmth of the Mid-Miocene Climatic Optimun in CESM1
title_fullStr The Challenge of Simulating the Warmth of the Mid-Miocene Climatic Optimun in CESM1
title_full_unstemmed The Challenge of Simulating the Warmth of the Mid-Miocene Climatic Optimun in CESM1
title_sort challenge of simulating the warmth of the mid-miocene climatic optimun in cesm1
publisher Purdue University
publishDate 2014
url https://docs.lib.purdue.edu/easpubs/185
https://docs.lib.purdue.edu/context/easpubs/article/1173/viewcontent/Mid_myocene_climaticOptimun_2014.pdf
geographic Antarctic
Pacific
geographic_facet Antarctic
Pacific
genre Antarc*
Antarctic
Ice Sheet
genre_facet Antarc*
Antarctic
Ice Sheet
op_source Department of Earth, Atmospheric, and Planetary Sciences Faculty Publications
op_relation https://docs.lib.purdue.edu/easpubs/185
https://docs.lib.purdue.edu/context/easpubs/article/1173/viewcontent/Mid_myocene_climaticOptimun_2014.pdf
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