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Modeling Northern Hemisphere ice-sheet distribution during MIS 5 and MIS 7 glacial inceptions (2014)

Colleoni, F. ; Masina, S. ; Cherchi, A. ; [et al.]

Copernicus

In: Climate of the Past. 2014; 10(1): 269-291. Published 2014 Feb 07. doi: 10.5194/cp-10-269-2014.

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Publication Date: 2014-02-07

Description: The present manuscript compares Marine Isotope Stage 5 (MIS 5, 125–115 kyr BP) and MIS 7 (236–229 kyr BP) with the aim to investigate the origin of the difference in ice-sheet growth over the Northern Hemisphere high latitudes between these last two inceptions. Our approach combines a low resolution coupled atmosphere–ocean–sea-ice general circulation model and a 3-D thermo-mechanical ice-sheet model to simulate the state of the ice sheets associated with the inception climate states of MIS 5 and MIS 7. Our results show that external forcing (orbitals and GHG) and sea-ice albedo feedbacks are the main factors responsible for the difference in the land-ice initial state between MIS 5 and MIS 7 and that our cold climate model bias impacts more during a cold inception, such as MIS 7, than during a warm inception, such as MIS 5. In addition, if proper ice-elevation and albedo feedbacks are not taken into consideration, the evolution towards glacial inception is hardly simulated, especially for MIS 7. Finally, results highlight that while simulated ice volumes for MIS 5 glacial inception almost fit with paleo-reconstructions, the lack of precipitation over high latitudes, identified as a bias of our climate model, does not allow for a proper simulation of MIS 7 glacial inception.

Print ISSN: 1814-9324

Electronic ISSN: 1814-9332

Topics: Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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Modelling Northern Hemisphere ice sheets distribution during MIS5 and MIS7 glacial inceptions (2012)

Colleoni, F. ; Masina, S. ; Cherchi, A. ; [et al.]

Copernicus

In: Climate of the Past Discussions. 2012; 8(6): 6221-6267. Published 2012 Dec 18. doi: 10.5194/cpd-8-6221-2012.

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Publication Date: 2012-12-18

Description: The present manuscript compares the last two glacial inceptions, Marine Isotope Stage 5 (MIS5, 125–115 kyr BP) and MIS7 (236–229 kyr BP) with the aim to detect the relative impact of external forcing (orbitals and GHG) and ice-albedo feedbacks on the ice sheets growth and distribution in the Northern Hemisphere high latitudes. In order to investigate the differences between those two states, we combine atmosphere-ocean coupled model experiments and off-line ice-sheet-model simulations. In particular, we use a low resolution coupled Atmosphere-Ocean-Sea-ice general circulation model to simulate the mean climate of the four time periods associated with the inception states of MIS5 and MIS7 (i.e. 236, 229, 125 and 115 kyr BP). The four mean states are then use to force a 3-D thermodynamical ice sheet model by means of two types of ice sheet experiments, i.e., steady-state and transient experiments. Our results show that steady-state ice experiments underestimate the ice volume at both 229 kyr BP and 115 kyr BP. On the other hand, the simulated pre-inception ice distributions at 236 kyr BP and 125 kyr BP are in good agreement with observations indicating that during these periods feedbacks associated with external forcing dominate over other processes. However, if proper ice-elevation and albedo feedbacks are not taken into consideration, the evolution towards glacial inception in terms of ice volume and extent is hardly simulated. The experimental setup chosen allows us to conclude that, depending on the mean background climate state, the effect of model biases on climate are more important during a cold inception, such as MIS7, than during a warm inception, such as MIS5. The last results suggest to be cautious when tuning and calibrating Earth System Models on a specific time period, mainly for the purpose of ice sheet-climate coupling.

Print ISSN: 1814-9340

Electronic ISSN: 1814-9359

Topics: Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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The double-ITCZ syndrome in coupled general circulation models: the role of large-scale vertical circulation regimes (2010)

Bellucci, A. ; Gualdi, S. ; Navarra, A.

American Meterological Society

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Publication Date: 2020-11-16

Description: The double-intertropical convergence zone (DI) systematic error, affecting state-of-the-art coupled general circulation models (CGCM) is examined in the multi-model Intergovernmental Panel on Climate Change (IPCC) Fourth Assessment Report (AR4) ensemble of simulations of the twentieth-century climate. Aim of this study is to quantify the DI error on precipitation in the tropical Pacific, with a specific focus on the relationship between the DI error and the representation of large-scale vertical circulation regimes in climate models. The DI rainfall signal is analysed using a regime sorting approach for the vertical circulation regimes. Through the use of this compositing technique, precipitation events are regime-sorted based on the large scale vertical motions, as represented by the mid-tropospheric lagrangian pressure tendency omega500 dynamical proxy. This methodology allows the partition of the precipitation signal into deep and shallow convective components. Following the regime-sorting diagnosis, the total DI bias is split into an error affecting the magnitude of precipitation associated with individual convective events and an error affecting the frequency of occurrence of single convective regimes. It is shown that, despite the existing large intra-model differences, CGCMs can be ultimately grouped into a few homegenous clusters, each featuring a well defined rainfall-vertical circulation relationship in the DI region. Three major behavioural clusters are identified within the AR4 models ensemble: two unimodal distributions, featuring maximum precipitation under subsidence and deep convection regimes, respectively, and one bimodal distribution, displaying both components. Extending this analysis to both coupled and uncoupled (atmosphere-only) AR4 simulations reveals that the DI bias in CGCMs is mainly due to the overly frequent occurrence of deep convection regimes, whereas the error on rainfall magnitude associated with individual convective events is overall consistent with errors already present in the corresponding atmosphere stand-alone simulations. A critical parameter controlling the strength of the DI systematic error is identified in the model-dependent sea surface temperature (SST) threshold leading to the onset of deep convection (THR), combined with the average SST in the south-eastern Pacific.

Description: Published

Description: 1127–1145

Description: 4A. Oceanografia e clima

Description: JCR Journal

Description: open

Keywords: double ITCZ ; climate models ; 01. Atmosphere::01.01. Atmosphere::01.01.02. Climate

Repository Name: Istituto Nazionale di Geofisica e Vulcanologia (INGV)

Type: article

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