Unraveling the mechanisms and implications of a stronger mid-Pliocene AMOC in PlioMIP2

Weiffenbach, Julia; Baatsen, Michiel; Heydt, Anna S. von der; Abe‐Ouchi, Ayako; Brady, Esther C.; Chan, Wing‐Le; Chandan, Deepak; Chandler, Mark A.; Contoux, Camille; Guo, Chuncheng; Han, Zixuan; Li, Qiang; Li, Xiangyu; Lohmann, Gerrit; Lunt, Daniel J.; Nisancioglu, Kerim H.; Otto‐Bliesner, Bette L.; Peltier, W. Richard; Sohl, Linda E.; Stepanek, Christian; Williams, Charles; Zhang, Qiong; Zhang, Zhongshi

doi:10.5194/cp-2022-35

Cited by 2 publications

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“…For example, high-latitude warming shown in proxy records persists in being generally underestimated by simulations, despite efforts to resolve data-model inconsistencies by altering the orbital parameters (Prescott et al 2014;Samakinwa et al 2020), increasing CO2 concentration (Stepanek et al 2020), including enhanced concentrations of non-CO2 (i.e. CH4) trace gases (Hopcroft et al 2020), and enhancing the poleward heat transport via closure of the Bering Strait (Chandan and Peltier 2017;Hunter et al 2019;Weiffenbach et al 2022).…”

Section: Introductionmentioning

confidence: 99%

Modeling the mid-Piacenzian warm climate using the water isotope-enabled Community Earth System Model (iCESM1.2)

Sun

Ding

et al. 2023

Preprint

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The mid-Piacenzian warm period (MPWP, ~3.264–3.025 Ma, previously referred to as the mid-Pliocene warm period), is the most recent geological period with atmospheric CO2 concentrations (400ppmv) close to today, but global surface temperatures were higher than today and in equilibrium with the CO2 concentrations. Therefore, the mid-Piacenzian equilibrated climate is often compared to the modern transient climate. In this study, we conduct a water isotope-enabled Community Earth System Model (iCESM1.2) simulation to study the large-scale features of the MPWP following the protocols of Pliocene Model Intercomparison Project Phase 2 (PlioMIP2). This MPWP simulation exhibits considerable warming in the high latitudes comparable to high-latitude MPWP surface warming evidenced in proxy records (i.e., polar amplification) that has been often underestimated in previous simulations. The improved performance of iCESM1.2over the PlioMIP2 models is due to a larger contribution of iCESM1.2-simulated downward clear-sky surface long wave radiation fluxes affecting polar amplification. Compared to the PI period, the total precipitation simulated by iCESM1.2 is generally wetter than the PlioMIP2 multi-model ensemble mean (MME) except for the opposite performance between iCESM1.2 and PlioMIP2 MME over the regions [~30S°–10N]. A heavier δ18Op during the MPWP mainly occurred in the tropical Indian ocean and surrounding Asian-African-Australian monsoon regions. There are contrasting changes in the tropical meridional and zonal atmospheric circulations (Hadley and Walker cells) during the MPWP. A weakened and expanded Hadley circulation (toward the poles) led to a reduction in tropical precipitation [~30S°–10N] and a poleward shift of the edge of the northern subtropical arid zone. In contrast, the tropical zonal atmospheric overturning circulation (Walker cell) and the global ocean meridional overturning circulation (MOC) are generally enhanced during the MPWP compared to the PI period.

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Section: Introductionmentioning

confidence: 99%

Modeling the mid-Piacenzian warm climate using the water isotope-enabled Community Earth System Model (iCESM1.2)

Sun

Ding

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

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Modeling the mid-piacenzian warm climate using the water isotope-enabled Community Earth System Model (iCESM1.2-ITPCAS)

Sun,

Ding,

et al. 2024

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The mid-Piacenzian Warm Period (MPWP, ~ 3.264–3.025 Ma) is the most recent example of a persistently warmer climate in equilibrium with atmospheric CO2 concentrations similar to today. Towards studying patterns and dynamics of a warming climate the MPWP is often compared to today. Following the Pliocene Model Intercomparison Project, Phase 2 (PlioMIP2) protocol we prepare a water isotope-enabled Community Earth System Model (iCESM1.2) simulation that is warmer and wetter than the PlioMIP2 multi-model ensemble (MME). While our simulation resembles PlioMIP2 MME in many aspects we find added insights. (1) Considerable warmth at high latitudes exceeds previous simulations. Polar amplification (PA) is comparable to proxies, enabled by iCESM1.2’s high climate sensitivity and a distinct method of ocean initialization. (2) Major driver of warmth is the downward component of clear-sky surface long-wave radiation ($$\varDelta T_{\text{rlds}\_\text{clearsky}}$$ Δ T rlds _ clearsky ). (3) In iCESM1.2 modulated dominance of dynamic (δDY) processes causes different low-latitude (~ 30 S°–10°N) precipitation response than the PlioMIP2 MME, where thermodynamic processes (δTH) dominate. (4) Modulated local condensation leads to lower δ18Op across tropical Indian Ocean and surrounding Asian-African-Australian monsoon regions. (5) We find contrasting changes in tropical atmospheric circulations (Hadley and Walker cells). Anomalous regional meridional (zonal) circulation, forced by changes in tropical-subtropical (tropical) diabatic processes, presents a more comprehensive perspective than explaining weakened and expanded Hadley circulation (strengthened and westward-shifted Walker circulation) via static stability. (6) Enhanced Atlantic meridional overturning circulation owes to a closed Bering Strait.

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Unraveling the mechanisms and implications of a stronger mid-Pliocene AMOC in PlioMIP2

Cited by 2 publications

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Modeling the mid-Piacenzian warm climate using the water isotope-enabled Community Earth System Model (iCESM1.2)

Modeling the mid-Piacenzian warm climate using the water isotope-enabled Community Earth System Model (iCESM1.2)

Modeling the mid-piacenzian warm climate using the water isotope-enabled Community Earth System Model (iCESM1.2-ITPCAS)

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