Polar amplification of Pliocene climate by elevated trace gas radiative forcing
(2020) In Proceedings of the National Academy of Sciences of the United States of America 117(38). p.23401-23407- Abstract
Warm periods in Earth's history offer opportunities to understand the dynamics of the Earth system under conditions that are similar to those expected in the near future. The Middle Pliocene warm period (MPWP), from 3.3 to 3.0 My B.P, is the most recent time when atmospheric CO2levels were as high as today. However, climate model simulations of the Pliocene underestimate highlatitude warming that has been reconstructed from fossil pollen samples and other geological archives. One possible reason for this is that enhanced non-CO2trace gas radiative forcing during the Pliocene, including from methane (CH4), has not been included in modeling. We use a suite of terrestrial biogeochemistry models forced with... (More)
Warm periods in Earth's history offer opportunities to understand the dynamics of the Earth system under conditions that are similar to those expected in the near future. The Middle Pliocene warm period (MPWP), from 3.3 to 3.0 My B.P, is the most recent time when atmospheric CO2levels were as high as today. However, climate model simulations of the Pliocene underestimate highlatitude warming that has been reconstructed from fossil pollen samples and other geological archives. One possible reason for this is that enhanced non-CO2trace gas radiative forcing during the Pliocene, including from methane (CH4), has not been included in modeling. We use a suite of terrestrial biogeochemistry models forced with MPWP climate model simulations from four different climate models to produce a comprehensive reconstruction of the MPWP CH4cycle, including uncertainty. We simulate an atmospheric CH4mixing ratio of 1,000 to 1,200 ppbv, which in combination with estimates of radiative forcing from N2O and O3, contributes a non-CO2radiative forcing of 0.9 Wm-2(range 0.6 to 1.1), which is 43% (range 36 to 56%) of the CO2radiative forcing used in MPWP climate simulations. This additional forcing would cause a global surface temperature increase of 0.6 to 1.0 °C, with amplified changes at high latitudes, improving agreement with geological evidence of Middle Pliocene climate. We conclude that natural trace gas feedbacks are critical for interpreting climate warmth during the Pliocene and potentially many other warm phases of the Cenezoic. These results also imply that using Pliocene CO2and temperature reconstructions alone may lead to overestimates of the fast or Charney climate sensitivity.
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- author
- Hopcroft, Peter O. ; Ramstein, Gilles ; Pugh, Thomas A.M. LU ; Hunter, Stephen J. ; Murguia-Flores, Fabiola ; Quiquet, Aurélien ; Sun, Yong ; Tan, Ning and Valdes, Paul J.
- publishing date
- 2020-09-22
- type
- Contribution to journal
- publication status
- published
- subject
- keywords
- Biogeochemistry, GCM, Methane, Pliocene, Trace gas, Wetland
- in
- Proceedings of the National Academy of Sciences of the United States of America
- volume
- 117
- issue
- 38
- pages
- 7 pages
- publisher
- National Academy of Sciences
- external identifiers
-
- pmid:32887804
- scopus:85087873117
- ISSN
- 0027-8424
- DOI
- 10.1073/pnas.2002320117
- language
- English
- LU publication?
- no
- id
- 936e3e92-8d9e-416e-ba17-4d77ab41c63c
- date added to LUP
- 2020-11-19 21:55:37
- date last changed
- 2024-06-28 04:16:04
@article{936e3e92-8d9e-416e-ba17-4d77ab41c63c,
abstract = {{<p>Warm periods in Earth's history offer opportunities to understand the dynamics of the Earth system under conditions that are similar to those expected in the near future. The Middle Pliocene warm period (MPWP), from 3.3 to 3.0 My B.P, is the most recent time when atmospheric CO<sub>2</sub>levels were as high as today. However, climate model simulations of the Pliocene underestimate highlatitude warming that has been reconstructed from fossil pollen samples and other geological archives. One possible reason for this is that enhanced non-CO<sub>2</sub>trace gas radiative forcing during the Pliocene, including from methane (CH<sub>4</sub>), has not been included in modeling. We use a suite of terrestrial biogeochemistry models forced with MPWP climate model simulations from four different climate models to produce a comprehensive reconstruction of the MPWP CH<sub>4</sub>cycle, including uncertainty. We simulate an atmospheric CH<sub>4</sub>mixing ratio of 1,000 to 1,200 ppbv, which in combination with estimates of radiative forcing from N2O and O3, contributes a non-CO<sub>2</sub>radiative forcing of 0.9 Wm<sup>-2</sup>(range 0.6 to 1.1), which is 43% (range 36 to 56%) of the CO<sub>2</sub>radiative forcing used in MPWP climate simulations. This additional forcing would cause a global surface temperature increase of 0.6 to 1.0 °C, with amplified changes at high latitudes, improving agreement with geological evidence of Middle Pliocene climate. We conclude that natural trace gas feedbacks are critical for interpreting climate warmth during the Pliocene and potentially many other warm phases of the Cenezoic. These results also imply that using Pliocene CO<sub>2</sub>and temperature reconstructions alone may lead to overestimates of the fast or Charney climate sensitivity.</p>}},
author = {{Hopcroft, Peter O. and Ramstein, Gilles and Pugh, Thomas A.M. and Hunter, Stephen J. and Murguia-Flores, Fabiola and Quiquet, Aurélien and Sun, Yong and Tan, Ning and Valdes, Paul J.}},
issn = {{0027-8424}},
keywords = {{Biogeochemistry; GCM; Methane; Pliocene; Trace gas; Wetland}},
language = {{eng}},
month = {{09}},
number = {{38}},
pages = {{23401--23407}},
publisher = {{National Academy of Sciences}},
series = {{Proceedings of the National Academy of Sciences of the United States of America}},
title = {{Polar amplification of Pliocene climate by elevated trace gas radiative forcing}},
url = {{http://dx.doi.org/10.1073/pnas.2002320117}},
doi = {{10.1073/pnas.2002320117}},
volume = {{117}},
year = {{2020}},
}